Acerola Kirazı Ekstraktı, güçlü antioksidan özellikleri ve cilt aydınlatıcı etkileriyle bilinen, Acerola kirazından elde edilen, doğal ve C vitamini açısından zengin bir bileşendir.
Acerola Kirazı Ekstraktı, cildi oksidatif stresten koruma, kolajen üretimini teşvik etme ve cilt parlaklığını artırma yeteneğiyle tanınır ve bu nedenle cilt bakım formülasyonlarında popüler bir tercihtir.
Bu çok yönlü ekstrakt, hem koruyucu hem de yenileyici faydalar sunarak, genç, canlı ve sağlıklı görünen bir cilt korunmasına yardımcı olur.

CAS Numarası: 84625-32-1
EC Numarası: 283-626-9

Eşanlamlılar: Acerola Kirazı Ekstraktı, Malpighia Glabra Meyve Ekstraktı, Acerola Meyve Ekstraktı, Acerola C Vitamini Ekstraktı, Acerola Antioksidan Ekstraktı, Acerola Kirazı Tozu, Acerola Kirazı Suyu Ekstraktı, Acerola Cilt Aydınlatıcı Ekstraktı, Acerola Kirazı Aktif, Acerola Meyve Suyu Ekstraktı, Acerola Fitoekstraktı, Acerola Biyoaktif Kompleksi, Acerola Kirazı Konsantresi, Acerola Meyve Ekstraktı, Acerola Doğal Ekstraktı, Acerola Cilt Bakım Aktifi, Acerola Vitamin Kompleksi, Acerola Aydınlatıcı Madde, Acerola Anti-Aging Ekstraktı, Acerola Kirazı Fitokompleksi



UYGULAMALAR


Acerola Kirazı Ekstraktı, ince çizgilerin ve kırışıklıkların görünümünü azaltmaya yardımcı olan güçlü antioksidan koruma sağladığı için anti-aging kremlerin formülasyonunda yaygın olarak kullanılır.
Acerola Kirazı Ekstraktı, cilt parlaklığını artıran ve kolajen sentezini destekleyen yoğun C vitamini faydaları sunduğu için serumların oluşturulmasında tercih edilir.
Acerola Kirazı Ekstraktı, cilt tonunu eşitlemeye ve koyu lekelerin görünümünü azaltmaya yardımcı olan aydınlatıcı tedavilerin geliştirilmesinde kullanılır.

Acerola Kirazı Ekstraktı, kuru ve olgun ciltler için nemlendirme ve antioksidan koruma sağladığı için nemlendirici kremlerin üretiminde yaygın olarak kullanılır.
Acerola Kirazı Ekstraktı, UV kaynaklı hasarlara karşı ek koruma sağlarken genel cilt direncini artırdığı için güneş kremleri formülasyonunda kullanılır.
Acerola Kirazı Ekstraktı, cilt sağlığını ve canlılığını artıran besleyici ve koruyucu faydalar sunarak yüz yağlarının oluşturulmasında esastır.

Acerola Kirazı Ekstraktı, şişlik, koyu halkalar ve göz çevresindeki yaşlanma belirtilerini azaltan hedeflenmiş antioksidan bakım sağladığı için göz kremlerinin üretiminde kullanılır.
Acerola Kirazı Ekstraktı, güneşe maruz kalan cilde yatıştırıcı ve koruyucu faydalar sağladığı için güneş sonrası ürünlerin formülasyonunda temel bir bileşendir.
Acerola Kirazı Ekstraktı, çevresel saldırganlara karşı cildin doğal savunmasını güçlendiren koruyucu serumların oluşturulmasında kullanılır.

Acerola Kirazı Ekstraktı, cildi canlandıran ve ferahlatan yoğun antioksidan bakımı sağlayan yüz maskelerinin formülasyonunda uygulanır.
Acerola Kirazı Ekstraktı, genel antioksidan koruma sağladığı ve cilt sıkılığı ve elastikiyetini teşvik ettiği için vücut losyonlarının üretiminde kullanılır.
Acerola Kirazı Ekstraktı, çevresel kirleticilere karşı koruyucu bir bariyer sağlarken cilt parlaklığını artıran anti-kirlilik cilt bakım ürünlerinin geliştirilmesinde kullanılır.

Acerola Kirazı Ekstraktı, saç derisi sağlığını destekleyen ve daha güçlü saçlar için antioksidan koruma sağlayan saç derisi tedavilerinin formülasyonunda yaygın olarak kullanılır.
Acerola Kirazı Ekstraktı, hassas ciltler için yatıştırıcı ve koruyucu faydalar sunarak iltihap önleyici cilt bakım ürünlerinin oluşturulmasında temel bir bileşendir.
Acerola Kirazı Ekstraktı, yumuşak ve pürüzsüz dudaklar için antioksidan koruma ve nem sağlayarak dudak bakım ürünlerinin üretiminde kullanılır.

Acerola Kirazı Ekstraktı, cildin mikrobiyomunu desteklerken güçlü antioksidan faydalar sağlayarak prebiyotik cilt bakım ürünlerinin formülasyonunda kullanılır.
Acerola Kirazı Ekstraktı, cilt yumuşaklığını korumaya ve ellerde yaşlanma belirtilerini azaltmaya yardımcı olan antioksidan koruma sağlayarak el kremleri oluşturulmasında uygulanır.
Acerola Kirazı Ekstraktı, günlük kullanım için dengeli nemlendirme, koruma ve anti-aging faydalar sunarak günlük kullanım kremlerinin geliştirilmesinde kullanılır.

Acerola Kirazı Ekstraktı, hasar görmüş veya yaşlanmış cildi onarmaya ve korumaya yardımcı olan yoğun bakım sağlayarak cilt onarım tedavilerinin formülasyonunda bulunur.
Acerola Kirazı Ekstraktı, gün boyu ferahlatıcı bir antioksidan koruma sunarak yüz spreylerinin üretiminde kullanılır.
Acerola Kirazı Ekstraktı, hassas cildi yatıştıran ve koruyan antioksidan bakım sunarak yatıştırıcı jellerin oluşturulmasında temel bir bileşendir.

Acerola Kirazı Ekstraktı, dudaklar, eller ve yüz gibi hassas bölgeler için çok yönlü bakım sağlayarak çok amaçlı balsamların formülasyonunda yaygın olarak kullanılır.
Acerola Kirazı Ekstraktı, kuru, pürüzlü ciltler için zengin nemlendirme ve antioksidan koruma sunarak besleyici vücut yağlarının geliştirilmesinde kullanılır.
Acerola Kirazı Ekstraktı, derin antioksidan koruma sağlayarak genç görünümlü cildi korumaya yardımcı olan yaşlanma karşıtı serumların üretiminde uygulanır.

Acerola Kirazı Ekstraktı, cilt sağlığını destekleyen ve oksidatif stresi azaltan besleyici bakım sunarak yüz yağlarının oluşturulmasında kullanılır.
Acerola Kirazı Ekstraktı, tahrişe ve rahatsızlığa eğilimli alanlar için hedeflenen bakım sağlayarak hassas cilt onarım tedavilerinin formülasyonunda bulunur.
Acerola Kirazı Ekstraktı, UV ışınlarına karşı koruma sağlarken cilt sağlığını koruyan antioksidan bakım sunarak güneş bakım ürünlerinin üretiminde kullanılır.



TANIM


Acerola Kirazı Ekstraktı, güçlü antioksidan özellikleri ve cilt aydınlatıcı etkileriyle bilinen, Acerola kirazından elde edilen, doğal ve C vitamini açısından zengin bir bileşendir.
Acerola Kirazı Ekstraktı, cildi oksidatif stresten koruma, kolajen üretimini teşvik etme ve cilt parlaklığını artırma yeteneğiyle tanınır ve bu nedenle cilt bakım formülasyonlarında popüler bir tercihtir.

Acerola Kirazı Ekstraktı, cilt dayanıklılığını artırmak ve genel cilt dokusunu iyileştirmek gibi ek faydalar sunarak uzun süreli koruma ve parlaklık sağlar.
Acerola Kirazı Ekstraktı, hem anında hem de uzun vadeli faydalar sunarak çevresel hasarlara karşı kapsamlı koruma sağlayan formülasyonlara sıklıkla dahil edilir.
Acerola Kirazı Ekstraktı, cildin genel sağlığını ve görünümünü iyileştirme kabiliyetiyle tanınır ve cildi pürüzsüz, canlı ve genç görünümde bırakır.

Acerola Kirazı Ekstraktı, hem geleneksel hem de yenilikçi cilt bakım formülasyonlarında yaygın olarak kullanılarak cilt sağlığını koruma ve sürdürme için güvenilir bir çözüm sunar.
Acerola Kirazı Ekstraktı, cildin doğal savunmasını destekleme kabiliyetiyle değerli görülmekte olup, çevresel saldırganlara karşı cildi korumayı amaçlayan ürünlerde kilit bir bileşendir.
Acerola Kirazı Ekstraktı, kremler, serumlar, yağlar ve losyonlar gibi çeşitli ürünlerde kullanılabilen çok yönlü bir bileşendir.

Acerola Kirazı Ekstraktı, yaşlanmış, stresli ve çevresel etkilere maruz kalmış cildi hedefleyen ürünler için ideal bir seçimdir, çünkü nazik ama etkili koruma ve gençleştirme sağlar.
Acerola Kirazı Ekstraktı, diğer cilt bakım aktifleriyle uyumluluğu ile bilinir, bu sayede çok fonksiyonlu formülasyonlara kolayca entegre edilebilir.
Acerola Kirazı Ekstraktı, koruma, gençleştirme ve cilt bakımı arasında denge gerektiren formülasyonlar için sıklıkla tercih edilmekte olup, tüm cilt tipleri için kapsamlı bakım sağlar.

Acerola Kirazı Ekstraktı, güçlü antioksidan koruma, cilt artırıcı etkiler ve çevresel savunma sağlayarak kişisel bakım ürünlerinin genel etkinliğini artırır.
Acerola Kirazı Ekstraktı, cilt sağlığında, parlaklığında ve dayanıklılığında gözle görülür iyileşmeler sunarak, keyifli bir kullanıcı deneyimi sunan ürünler oluşturmak için güvenilir bir bileşendir.
Acerola Kirazı Ekstraktı, performansları, güvenlikleri ve cildi koruma ve geliştirme yetenekleri ile öne çıkan yenilikçi cilt bakım ürünlerinin temel bir bileşenidir.



ÖZELLİKLER


Kimyasal Formül: N/A (Doğal ekstrakt)
Yaygın Adı: Acerola Kirazı Ekstraktı (Malpighia Glabra Meyve Ekstraktı)
Moleküler Yapı:
Görünüm: Açık sarı ila turuncu sıvı veya toz
Yoğunluk: Yaklaşık 1.03-1.08 g/cm³ (sıvı ekstrakt için)
Erime Noktası: N/A (sıvı veya toz formu)
Çözünürlük: Suda ve alkolde çözünür; yağlarda çözünmez
Alev Alma Noktası: >100°C (sıvı ekstrakt için)
Reaktivite: Normal koşullar altında stabil; bilinen bir reaktivite sorunu yok
Kimyasal Stabilite: Tavsiye edilen saklama koşullarında stabil
Saklama Sıcaklığı: Serin, kuru bir yerde 15-25°C arasında saklayın
Buhar Basıncı: Düşük (sıvı ekstrakt için)



İLK YARDIM


Soluma:
Acerola Kirazı Ekstraktı solunduğunda, etkilenen kişiyi hemen temiz havaya çıkarın.
Solunum güçlüğü devam ederse derhal tıbbi yardım alın.
Kişi nefes almıyorsa suni solunum uygulayın.
Etkilenen kişiyi sıcak tutun ve dinlenmesini sağlayın.

Cilt Teması:
Etkilenen bölgeyi su ve sabunla yıkayın.
Cilt tahrişi devam ederse tıbbi yardım alın.

Göz Teması:
Göz temasında, gözleri en az 15 dakika boyunca bol su ile yıkayın, üst ve alt göz kapaklarını kaldırarak.
Tahriş veya kızarıklık devam ederse derhal tıbbi yardım alın.
Varsa ve kolayca çıkarılabiliyorsa, kontakt lensleri çıkarın; durulamaya devam edin.

Yutma:
Acerola Kirazı Ekstraktı yutulursa, tıbbi personel tarafından önerilmedikçe kusmayı teşvik etmeyin.
Ağzı bol su ile iyice çalkalayın.
Derhal tıbbi yardım alın.
Kişi bilinçliyse küçük yudumlar halinde su içirin.

Doktorlara Not:
Semptomatik tedavi uygulayın.
Spesifik bir antidot yoktur.
Destekleyici bakım sağlayın.



KULLANIM VE DEPOLAMA


Kullanım:

Kişisel Koruma:
Büyük miktarlarda işlem yaparken uygun kişisel koruyucu ekipman (KKD) olarak eldiven ve koruyucu gözlük takın.
Buharların solunmasını önlemek için iyi havalandırılan bir alanda kullanın.

Havalandırma:
Büyük miktarlarda Acerola Kirazı Ekstraktı işlenirken, havadaki konsantrasyonların mesleki maruziyet sınırlarının altında kontrol edilmesi için yeterli havalandırma sağlayın.

Kaçınma:
Gözle doğrudan temas ve uzun süreli cilt temasından kaçının.
Acerola Kirazı Ekstraktı kullanırken yemek yemeyin, içmeyin veya sigara içmeyin.
Kullanımdan sonra ellerinizi iyice yıkayın.

Dökülme ve Sızıntı Prosedürleri:
Dökülmeleri önlemek için kontrol altına alın ve maruziyeti en aza indirin.
İnert malzeme (örneğin kum, vermikülit) ile emdirin ve bertaraf için toplayın.
Yerel düzenlemelere uygun şekilde bertaraf edin.

Depolama:
Acerola Kirazı Ekstraktı'nı serin, kuru ve iyi havalandırılan bir alanda, uyumsuz maddelerden (spesifik detaylar için SDS'ye bakın) uzakta saklayın.
Kirlenmeyi önlemek için kullanmadığınızda kapları sıkıca kapalı tutun.
Isı kaynaklarından, doğrudan güneş ışığından ve tutuşturucu kaynaklardan uzak tutun.

Kullanım İhtiyatları:
Buharların solunmasından ve cilt ve gözlerle doğrudan temastan kaçının.
Buharların bulunabileceği alanlarda patlamaya dayanıklı ekipman kullanın.


Depolama:

Sıcaklık:
Acerola Kirazı Ekstraktı'nı üreticinin önerdiği şekilde 15-25°C arasında saklayın.
Aşırı sıcaklıklara maruz bırakmaktan kaçının.

Kaplar:
Uygun kaplama malzemelerinden yapılmış onaylı kapları kullanın.
Depolama kaplarında sızıntı veya hasar olup olmadığını düzenli olarak kontrol edin.

Ayrım:
Acerola Kirazı Ekstraktı'nı güçlü oksitleyiciler gibi uyumsuz maddelerden uzak tutarak saklayın.

Kullanım Ekipmanları:
Çapraz kontaminasyonu önlemek için Acerola Kirazı Ekstraktı'nın işlenmesi için özel ekipman kullanın.
Tüm işleme ekipmanlarının iyi durumda olduğundan emin olun.

Güvenlik Önlemleri:
Depolama alanlarına erişimi kısıtlayın.
Kozmetik bileşenlerin depolanmasıyla ilgili tüm yerel düzenlemelere uyun.

Acil Durum Yanıtı:
Dökülme temizleme malzemeleri, yangın söndürücüler ve acil göz yıkama istasyonları dahil olmak üzere acil durum yanıt ekipmanı ve malzemelerini hazır bulundurun.

N-2-hydroxyethylacetamide, Acetamide MEA 100%, 2-Acetamidoethanol; 2-Acetylaminoethanol; 2-N-Acetylaminoethanol; Acetamide MEA; Acetylcolamine; Incromectant AMEA 100; Incromectant AMEA 70; Mackamide AME 100; N-(b-Hydroxyethyl)acetamide; N-Acetyl-2-aminoethanol; N-Acetylethanolamine; N-Ethanolacetamide; NSC 5999; Schercomid AME 70 CAS Number 142-26-7

Acesulfame potassium; Potassium acesulfame; Sunett;6-Methyl-3,4-dihydro-1,2,3-oxathiazin-4-one 2,2-dioxide potassium salt; 1,2,3-Oxathiazin-4(3H)-one, 6-methyl-, 2,2-dioxide potassium salt; 6-Methyl-1,2,3-oxathiazin-4(3H)-one-2,2-dioxide potassium; Sweet one; cas no: 55589-62-3

Acesulfame potassium; Potassium acesulfame; Sunett; 6-Methyl-3,4-dihydro-1,2,3-oxathiazin-4-one 2,2-dioxide potassium salt; 1,2,3-Oxathiazin-4(3H)-one, 6-methyl-, 2,2-dioxide potassium salt; 6-Methyl-1,2,3-oxathiazin-4(3H)-one-2,2-dioxide potassium; Sweet one; CAS NO:55589-62-3, 33665-90-6 (Parent)

SYNONYMS Acesulfame potassium; Potassium acesulfame; Sunett; 6-Methyl-3,4-dihydro-1,2,3-oxathiazin-4-one 2,2-dioxide potassium salt; 1,2,3-Oxathiazin-4(3H)-one, 6-methyl-, 2,2-dioxide potassium salt; 6-Methyl-1,2,3-oxathiazin-4(3H)-one-2,2-dioxide potassium; Sweet one; CAS NO. 55589-62-3

ACETAMIDOETHOXYETHANOL, N° CAS :118974-46-2, ACETAMIDOETHOXYETHANOL, Acetamide, N-[2-(2-hydroxyethoxy)ethyl]-. Ses fonctions (INCI) :Humectant : Maintient la teneur en eau d'un cosmétique dans son emballage et sur la peau

AMMONIUM ACETATE, N° CAS : 631-61-8 , Acétate d'ammonium, Nom INCI : AMMONIUM ACETATE, Nom chimique : Ammonium acetate, N° EINECS/ELINCS : 211-162-9, Additif alimentaire : E264, Ses fonctions (INCI), Régulateur de pH : Stabilise le pH des cosmétiques

ElfaMoist® AC Humectant , Acetamide, N-[2-(2-hydroxyethoxy)ethyl]- CAS : 118974-46-2

AMYL ACETATE, N° CAS : 628-63-7, Nom INCI : AMYL ACETATE, Nom chimique : Pentyl acetate, N° EINECS/ELINCS : 211-047-3. Ses fonctions (INCI): Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Solvant : Dissout d'autres substances. 1-Pentanol, acetate; 211-047-3 [EINECS]; Noms français : 1-PENTANOL ACETATE; 1-PENTYL ACETATE ACETATE D'AMYLE; ACETIC ACID, PENTYL ESTER; Acétate d'amyle normal; Acétate de 1-pentyle; Acétate de n-amyle; AMYL ACETATE NORMAL; n-Amyl acetate; NORMAL-AMYL ACETATE PENTANOL ACETATE; Pentyl acetate; Noms anglais :Acetic acid, amyl ester; Amyl acetate (normal-); Amyl acetic ester; Amyl acetic ether; n-Amyl acetate; n-Pentyl acetate; Normal amyl acetate Pent-acetate; Pentyl acetate, all isomers [628-63-7]; Famille chimique; Ester; Utilisation L'acétate d'amyle normal est utilisé : comme solvant dans les laques àbase de nitrocellulose, les vernis, les peintures, les vernis àongles, les parfums, les ciments et les lampes fluorescentes; comme solvant dans l'industrie photographique (pellicules) et dans l'industrie textile (soie, cuir artificiel); comme nettoyant de taches dans l'industrie du nettoyage àsec; comme agent de saveur dans l'industrie alimentaire; dans l'industrie pharmaceutique. 628-63-7 [RN] Acétate de pentyle [French] Acetic acid n-amyl ester Acetic acid n-pentyl ester Acetic acid, n-pentyl ester Acetic acid, pentyl ester Amyl Acetate Amyl acetate, n- n-Pentyl acetate n-PENTYL ETHANOATE Pentyl acetate Pentyl ethanoate Pentylacetat Pentyl-acetat [German] 1-Acetoxypentane 1-Pentanol acetate 1-Pentyl acetate Acetate d'amyle [French] Acetic acid amyl ester Acetic acid pentyl ester Acetic acid, amyl ester Acetic acid, N-amyl ester Amyl acetate211-047-3MFCD00009500 Amyl acetic ester Amyl acetic ether Amylacetate Amylazetat [German] Amylester kyseliny octove [Czech] banana oil [Wiki] Birnenoel N-Amyl acetate Octan amylu [Polish] Pear oil Pent-acetate pentanol acetate Prim-amyl acetate Primary amyl acetate

BENZYL ACETATE, N° CAS : 140-11-4 / 101-41-7, Nom INCI : BENZYL ACETATE. Nom chimique : Methyl Phenylacetate; Methyl alpha-Toluate. N° EINECS/ELINCS : 205-399-7 / 202-940-9. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques

BUTYL ACETATE, N° CAS : 123-86-4 - Acétate de butyle, Origine(s) : Synthétique. Nom INCI : BUTYL ACETATE. Nom chimique : n-Butyl acetate. N° EINECS/ELINCS : 204-658-1. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Solvant : Dissout d'autres substances

propan-2-yl 2-methoxyacetate

POTASSIUM ACETATE, N° CAS : 127-08-2 - Acétate de potassium, Nom INCI : POTASSIUM ACETATE. Nom chimique : Potassium acetate. N° EINECS/ELINCS : 204-822-2. Additif alimentaire :E261, Ses fonctions (INCI), Agent filmogène : Produit un film continu sur la peau, les cheveux ou les ongles

STRONTIUM ACETATE, N° CAS : 543-94-2 - Acétate de strontium (hémihydraté), Nom INCI : STRONTIUM ACETATE, Nom chimique : Strontium di(acetate), N° EINECS/ELINCS : 208-854-8 Classification : Règlementé. Ses fonctions (INCI) : Agent d'hygiène buccale : Fournit des effets cosmétiques àla cavité buccale (nettoyage, désodorisation et protection). Agent apaisant : Aide àalléger l'inconfort de la peau ou du cuir chevelu

Acétate de la vitamine E (+); Acétate de vitamine E; ALPHA-TOCOPHEROL ACETATE (+); D-.ALPHA.-TOCOPHERYL ACETATEalpha-Tocopherol acetate; tocopherol acetate; α-tocopheryl acetate; TOCOPHERYL ACETATE, N° CAS : 7695-91-2 / 58-95-7 - Acétate de tocophérol, Origine(s) : Végétale, Synthétique. Autres langues : Acetato de tocoferilo, Acetato di tocoferile, Tocopherylacetat, Nom INCI : TOCOPHERYL ACETATE. Nom chimique : 3,4-Dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-benzopyran-6-yl acetate, N° EINECS/ELINCS : 231-710-0 / 200-405-4. L'acétate de tocophérol est un dérivé de Vitamine E. Il agit dans les cosmétiques en tant qu'antioxydant. Il peut être produit synthétiquement ou d'origine naturel, extrait d'huile de Soja ou de tournesol par exemple. Il est souvent utilisé dans les cosmétiques en tant qu'alternative au tocophérol pur, parce qu'il est considéré plus stable et moins acide. Il est autorisé en bio, lorsqu'il est d'origine végétal.Ses fonctions (INCI) : Antioxydant : Inhibe les réactions favorisées par l'oxygène, évitant ainsi l'oxydation et la rancidité. Agent d'entretien de la peau : Maintient la peau en bon état; (+)-α-Tocopherol acetate (2R)-2,5,7,8-Tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-3,4-dihydro-2H-chromen-6-yl acetate [ACD/IUPAC Name] (2R)-2,5,7,8-Tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-3,4-dihydro-2H-chromen-6-yl-acetat [German] [ACD/IUPAC Name] [2R*(4R*,8R*)]-3,4-Dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-1-benzopyran-6-ol Acetate 200-405-4 [EINECS] 231-710-0 [EINECS] 2H-1-Benzopyran-6-ol, 3,4-dihydro-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-, acetate, (2R)- [ACD/Index Name] 58-95-7 [RN] 7695-91-2 [RN] A7E6112E4N Acétate de (2R)-2,5,7,8-tétraméthyl-2-[(4R,8R)-4,8,12-triméthyltridécyl]-3,4-dihydro-2H-chromén-6-yle [French] [ACD/IUPAC Name] all-rac-α-tocopheryl acetate a-Tocopherol Acetate a-Tocopheryl Acetate D-?-tocopherol acetate Eprolin [Trade name] E-Vimin Evion GA8747000 GP8280000 MFCD00072042 [MDL number] MFCD00072052 O-Acetyl-α-tocopherol TOCOPHEROL ACETATE [JP15] Tocopheryl acetate [Wiki] Tocopheryl Acetate, a Vitamin E acetate Vitamin- E acetate α Tocopheryl Acetate α-Tocopherol acetate α-Tocopherylis acetas α-Tocopherol acetate ()-α-Tocopherol acetate (?)-?-Tocopheryl acetate (+)-?-Tocopherol acetate (+)-α-tocopherol acetate (2R-(2R*(4R*,8R*)))-3,4-Dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-1-benzopyran-6-ol acetate (2R*(4R*,8R*))-(1)-3,4-Dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-benzopyran-6-yl acetate [(2R)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-3,4-dihydrochromen-6-yl] acetate [(2R)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]chroman-6-yl] acetate [(2R)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]chroman-6-yl] ethanoate [(2S)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]chroman-6-yl] acetate [(2S)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]chroman-6-yl] ethanoate [2R*(4R*,8R*)]-()-3,4-dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-benzopyran-6-yl acetate [58-95-7] [7695-91-2] 133-80-2 [RN] 1407-18-7 [RN] 18920-61-1 [RN] 2,5,7,8-Tetramethyl-2-(4,8,12-trimethyltridecyl)-3,4-dihydro-2H-chromen-6-yl acetate [ACD/IUPAC Name] 200-412-2 [EINECS] 2H-1-Benzopyran-6-ol, 3,4-dihydro-2,5,7,8-tetramethyl-2-((4R,8R)-4,8,12-trimethyltridecyl)-, acetate, (2R)- 2H-1-Benzopyran-6-ol, 3,4-dihydro-2,5,7,8-tetramethyl-2-((4R,8R)-4,8,12-trimethyltridecyl)-, acetate, (2R)-rel- 2H-1-Benzopyran-6-ol, 3,4-dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-, acetate, [2R-[2R*(4R*,8R*)]]- 2H-1-Benzopyran-6-ol, 3,4-dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-, acetate,(2R*(4R*,8R*))-(±)- 2H-1-Benzopyran-6-ol,3,4-dihydro-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-,6-acetate, (2R)-rel- 3,4-Dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-b- enzopyran-6-ol, acetate 3,4-Dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H-benzopyran-6-yl acetate 5-17-04-00169 [Beilstein] 5-17-04-00169 (Beilstein Handbook Reference) [Beilstein] 54-22-8 [RN] 6-acetoxy-2,5,7,8-tetramethyl-2-(4',8',12'-trimethyltridecyl)-chromane 6-Chromanol, 2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-, acetate Acetic acid (R)-2,5,7,8-tetramethyl-2-((4R,8R)-4,8,12-trimethyl-tridecyl)-chroman-6-yl ester acetic acid [(2R)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-6-chromanyl] ester acetic acid [(2R)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]chroman-6-yl] ester acetic acid [(2S)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]-6-chromanyl] ester acetic acid [(2S)-2,5,7,8-tetramethyl-2-[(4R,8R)-4,8,12-trimethyltridecyl]chroman-6-yl] ester Acetic acid 2,5,7,8-tetramethyl-2-(4,8,12-trimethyl-tridecyl)-chroman-6-yl ester Alfacol all-rac-2,5,7,8-Tetramethyl-2-(4,8,12-trimethyltridecyl)-3,4-dihydro-2H-1-benzopyran-6-yl acetate all-rac-α-Tocopheryl acetate Contopheron d-??Tocopheryl Acetate d-a-tocopheryl acetate DL-??-Tocopherol Acetate DL-?-Tocopherol Acetate DL-��-Tocopherol Acetate DL-α-Tocopherol acetate DL-α-Tocopheryl acetate DL-��-Tocopherol Acetate DL-α-Tocopherol acetate, 50% powder form DL-α-Tocopherol acetate, EP/USP/FCC grade DL-α-Tocopherylacetate (Vitamin E acetate) D-α tocoferil acetate d-α Tocopheryl Acetate d-α-tocopherol acetate D-α-Tocopherol Acetate D-α-TOCOPHEROLACETATE D-α-Tocopheryl acetate d-α-tocopheryl acetate, 97% Ecofrol ECON E-ferol EINECS 231-710-0 EINECS 257-757-7 Endo E dompe Ephynal Epsilan-M E-Toplex Evipherol Fertilvit Gevex α-Tocopherol Acetate α-Tocopherylis acetas Juvela [Trade name] NCGC00166253-01 O-Acetyl-α-tocopherol Rovimix E 50SD RRR-α-tocopheryl acetate Syntopherol acetate Tocopherex Tocopherol acetate (JP15) Tocopherolacetate, α- Tocophrin TOFAXIN UNII:A7E6112E4N UNII-A7E6112E4N UNII-WR1WPI7EW8 Vectan Vectan (TN) vitamin e acetate 96% Vitamin E Acetate Oil - Synthetic Vitamin E acetate, d- vitamin e acetate α-tocopherol acetate α-Tocopherol acetate, all rac α-TOCOPHEROL ACETATE, D- α-TOCOPHEROL ACETATE, DL- α-Tocopheryl acetate α-Tocopheryl acetate α-tocopheryl acetate, D-

ZINC ACETATE N° CAS : 557-34-6 - Acétate de zinc "Satisfaisant" dans toutes les catégories. Nom INCI : ZINC ACETATE Nom chimique : Zinc di(acetate) N° EINECS/ELINCS : 209-170-2 Additif alimentaire : E650 Classification : Règlementé Restriction en Europe : III/24 La concentration maximale autorisée en cosmétique est la suivante : 1 % (en zinc). Ses fonctions (INCI) Antimicrobien : Aide àralentir la croissance de micro-organismes sur la peau et s'oppose au développement des microbes

CETYL ACETATE, N° CAS : 629-70-9, Nom INCI : CETYL ACETATE, Nom chimique : Hexadecyl acetate, N° EINECS/ELINCS : 211-103-7, Emollient : Adoucit et assouplit la peau, Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit, Agent d'entretien de la peau : Maintient la peau en bon état; Hexadecyl acetate; 1-Hexadecanol, 1-acetate; Cetyl acetate; Cetyl acetate 1-Hexadecanol, acetate [ACD/Index Name]; Acétate d'hexadécyle [French] ; Cetyl alcohol acetate; Hexadecyl acetate ; Hexadecyl-acetat [German] ; 1-Acetoxyhexadecane; 1-Hexadecanol acetate; 1-Hexadecanol, 1-acetate; 1-Hexadecyl acetate; Acelan A; acetic acid cetyl ester; acetic acid hexadecyl ester; Acetic acid, hexadecyl ester; CETYL ACETATE|HEXADECYL ACETATE; Hexadecanol acetate; Hexadecanyl acetate; hexadecyl ethanoate; n-Hexadecyl acetate; n-Hexadecyl ethanoate; Palmityl acetate

Ethylic acid; Methanecarboxylic acid; vinegar; Vinegar acid; Acetic acid, glacial; Essigsäure; ácido acético; Acide acétique; Ethanoic acid; Acetasol; Octowy kwas; Kyselina octova; Essigsaeure; Octowy kwas; Vosol; CHLORINE IODIDE; CHLOROIODIDE; IODINE CHLORIDE; IODINE MONOCHLORIDE; IODINE MONOCHLORIDE SOLUTION, WIJS; IODINE-MONOCHLORIDE, WIJS; IODINE SOLUTION ACCORDING TO WIJS; IODOCHLORIDE; IODOMONOCHLORIDE; WIJS CHLORIDE; WIJS' CHLORIDE; WIJS IODINE SOLUTION; WIJ'S IODINE SOLUTION; WIJS REAGENT; WIJS' REAGENT; WIJS SOLUTION; WIJS' SOLUTION; Acetasol; aceticacid(non-specificname); aceticacid(solutionsgreaterthan10%) CAS NO:64-19-7, 77671-22-8

SYNONYMS Ethylic acid; Methanecarboxylic acid; vinegar; Vinegar acid; Acetic acid, glacial; CAS NO. 64-19-7, 77671-22-8

Ethylic acid; Methanecarboxylic acid; vinegar; Vinegar acid; Acetic acid, glacial; Essigsäure; ácido acético; Acide acétique; Ethanoic acid; Acetasol; Octowy kwas; Kyselina octova; Essigsaeure; Octowy kwas; Vosol CAS NO:64-19-7

Acetic Acid 80% is completely soluble in water.
Acetic Acid 80% is a chemical reagent for the production of chemicals.


CAS Number: 64-19-7
EC Number: 200-580-7
E number: E260 (preservatives)
Molecular Formula: C2H4O2 / CH3COOH



SYNONYMS:
Acetic acid, Ethanoic acid, Vinegar (when dilute), Hydrogen acetate, Methanecarboxylic acid, Ethylic acid, Ethanoic acid, Ethylic acid, Glacial acetic acid, Methanecarboxylic acid, Vinegar acid, CH3COOH, Acetasol, Acide acetique, Acido acetico, Azijnzuur, Essigsaeure, Octowy kwas, Acetic acid, glacial, Kyselina octova, UN 2789, Aci-jel, Shotgun, Ethanoic acid monomer, NSC 132953, Ethanoic acid, vinegar, ethylic acid, vinegar acid, methanecarboxylic acid, TCLP extraction fluid 2, shotgun, glacial acetic acid, glacial ethanoic acid, Ethanoic acid, Ethylic acid, Glacial acetic acid, Methanecarboxylic acid, Vinegar acid, CH3COOH, Acetasol, Acide acetique, Acido acetico, Azijnzuur, Essigsaeure, Octowy kwas, Acetic acid, glacial, Kyselina octova, UN 2789, Aci-jel, Shotgun, Ethanoic acid monomer, NSC 132953, BDBM50074329, FA 2:0, LMFA01010002, NSC132953, NSC406306, Acetic acid for HPLC >=99.8%, AKOS000268789, ACIDUM ACETICUM [WHO-IP LATIN], DB03166, UN 2789, Acetic acid >=99.5% FCC FG, Acetic acid natural >=99.5% FG, Acetic acid ReagentPlus(R) >=99%, CAS-64-19-7, USEPA/OPP Pesticide Code: 044001, Acetic acid USP 99.5-100.5%, NCGC00255303-01, Acetic acid 1000 microg/mL in Methanol, Acetic acid SAJ first grade >=99.0%, Acetic acid 1000 microg/mL in Acetonitrile, Acetic acid >=99.99% trace metals basis, Acetic acid JIS special grade >=99.7%, Acetic acid purified by double-distillation, NS00002089, Acetic acid UV HPLC spectroscopic 99.9%, EN300-18074, Acetic acid Vetec(TM) reagent grade >=99%, Bifido Selective Supplement B for microbiology, C00033, D00010, ORLEX HC COMPONENT ACETIC ACID GLACIAL, Q47512, VOSOL HC COMPONENT ACETIC ACID GLACIAL, Acetic acid glacial electronic grade 99.7%, TRIDESILON COMPONENT ACETIC ACID GLACIAL, A834671, ACETASOL HC COMPONENT ACETIC ACID GLACIAL, Acetic acid >=99.7% SAJ super special grade, ACETIC ACID GLACIAL COMPONENT OF BOROFAIR, ACETIC ACID GLACIAL COMPONENT OF ORLEX HC, ACETIC ACID GLACIAL COMPONENT OF VOSOL HC, SR-01000944354, ACETIC ACID GLACIAL COMPONENT OF TRIDESILON, SR-01000944354-1, ACETIC ACID GLACIAL COMPONENT OF ACETASOL HC, Glacial acetic acid meets USP testing specifications, InChI=1/C2H4O2/c1-2(3)4/h1H3(H,3,4), Acetic acid >=99.7% suitable for amino acid analysis, Acetic acid >=99.7% for titration in non-aqueous medium, Acetic acid for luminescence BioUltra >=99.5% GC, Acetic acid p.a. ACS reagent reag. ISO reag. Ph. Eur. 99.8%, Acetic acid semiconductor grade MOS PURANAL(TM) Honeywell 17926, Glacial acetic acid United States Pharmacopeia USP Reference Standard, Acetic acid puriss. p.a. ACS reagent reag. ISO reag. Ph. Eur. >=99.8%, Glacial Acetic Acid Pharmaceutical Secondary Standard Certified Reference Material, Acetic acid puriss. meets analytical specification of Ph. Eur. BP USP FCC 99.8-100.5%, acetic-acid, Glacial acetate, acetic cid, actic acid, UNII-Q40Q9N063P, acetic -acid, Distilled vinegar, Methanecarboxylate, Acetic acid glacial [USP:JAN], Acetasol (TN), Acetic acid glacial for LC-MS, Vinegar (Salt/Mix), HOOCCH3, 546-67-8, Acetic acid LC/MS Grade, ACETIC ACID [II], ACETIC ACID [MI], Acetic acid ACS reagent, bmse000191, bmse000817, bmse000857, Otic Domeboro (Salt/Mix), EC 200-580-7, Acetic acid (JP17/NF), ACETIC ACID [FHFI], ACETIC ACID [INCI], Acetic Acid [for LC-MS], ACETIC ACID [VANDF], NCIOpen2_000659, NCIOpen2_000682, Acetic acid glacial (USP), 4-02-00-00094 (Beilstein Handbook Reference), 77671-22-8, Glacial acetic acid (JP17), UN 2790 (Salt/Mix), ACETIC ACID [WHO-DD], ACETIC ACID [WHO-IP], ACETICUM ACIDUM [HPUS], GTPL1058, Acetic Acid Glacial HPLC Grade, Acetic acid analytical standard, Acetic acid Glacial USP grade, Acetic acid puriss. >=80%, Acetic acid 99.8% anhydrous, Acetic acid AR >=99.8%, Acetic acid LR >=99.5%, Acetic acid extra pure 99.8%, Acetic acid 99.5-100.0%, Acetic acid Glacial ACS Reagent, STR00276, Acetic acid puriss. 99-100%, Tox21_301453, Acetic acid glacial >=99.85%, acetic acid, ethanoic acid, 64-19-7, Ethylic acid, Vinegar acid, Acetic acid glacial, Glacial acetic acid, Acetic acid glacial, Methanecarboxylic acid, Acetasol, Essigsaeure, Acide acetique, Pyroligneous acid, Vinegar, Azijnzuur, Aceticum acidum, Acido acetico, Octowy kwas, Aci-jel, HOAc, ethoic acid, Kyselina octova, Orthoacetic acid, AcOH, Ethanoic acid monomer, Acetic, Caswell No. 003, Otic Tridesilon, MeCOOH, Acetic acid-17O2, Otic Domeboro, Acidum aceticum glaciale, Acidum aceticum, CH3-COOH, acetic acid-, CH3CO2H, UN2789, UN2790, EPA Pesticide Chemical Code 044001, NSC 132953, NSC-132953, NSC-406306, BRN 0506007, Acetic acid diluted, INS NO.260, Acetic acid [JAN], DTXSID5024394, MeCO2H, CHEBI:15366, AI3-02394, CH3COOH, INS-260, Q40Q9N063P, E-260, 10.Methanecarboxylic acid, CHEMBL539, NSC-111201, NSC-112209, NSC-115870, NSC-127175, Acetic acid-2-13C,d4, INS No. 260, DTXCID304394, E 260, Acetic-13C2 acid (8CI,9CI), Ethanoat, Shotgun, MFCD00036152, Acetic acid of a concentration of more than 10 per cent by weight of acetic acid, 285977-76-6, 68475-71-8, C2:0, acetyl alcohol, Orlex, Vosol, ACETIC-1-13C-2-D3 ACID-1 H (D), WLN: QV1, ACETIC ACID (MART.), ACETIC ACID [MART.], Acetic acid >=99.7%, 57745-60-5, 63459-47-2, FEMA Number 2006, ACETIC-13C2-2-D3 ACID, 97 ATOM % 13C, 97 ATOM % D, Acetic acid ACS reagent >=99.7%, ACY, HSDB 40, CCRIS 5952, 79562-15-5, methane carboxylic acid, EINECS 200-580-7, Acetic acid 0.25% in plastic container, Essigsaure, Ethylate, acetic acid, ethanoic acid, ethylic acid, acetic acid, glacial, methanecarboxylic acid, vinegar acid, glacial, acetasol, acide acetique, essigsaeure,



Acetic Acid 80% is an organic acid available in various standard strengths.
Pure Acetic Acid 80% is known as Acetic Acid 80% Glacial because it will freeze at moderate temperatures (16.6C).
Acetic Acid 80% is an organic compound with the chemical formula CH3COOH (also written as CH3CO2H or C2H4O2).


Acetic Acid 80% is a colourless liquid which when undiluted is also called ‘glacial Acetic Acid 80%’.
Acetic Acid 80%, CH3COOH, also known as ethanoic acid, is an organic acid which has a pungent smell.
Acetic Acid 80% is a weak acid, in that it is only partially dissociated in an aqueous solution.


Acetic Acid 80% is hygroscopic (absorbs moisture from the air) and freezes at 16.5C to a colourless crystalline solid.
Acetic Acid 80% is one of the simplest carboxylic acids, and is a very important industrial chemical.
Acetic Acid 80% is produced by biological and synthetic ways in the industry.


The salt and Acetic Acid 80%'s ester are called acetate.
Acetic Acid 80% is completely soluble in water.
Acetic Acid 80% is a chemical reagent for the production of chemicals.


The most common one-time use of Acetic Acid 80% is for the production of vinyl acetate monomer as well as the production of acetic anhydride and esters.
Acetic Acid 80% is the main component of vinegar (apart from water; vinegar is roughly 8% Acetic Acid 80% by volume), and has a distinctive sour taste and pungent smell.


Acetic Acid 80% Food Grade is one of the simplest carboxylic acids.
Acetic Acid 80% is an important chemical reagent and industrial chemical, mainly used in the production of cellulose acetate for photographic film and polyvinyl acetate for wood glue, as well as synthetic fibres and fabrics.


Acetic Acid 80%, also known as ethanoic acid, is a colourless liquid and organic compound.
With the chemical formula CH₃COOH, Acetic Acid 80% is a chemical reagent for the production of chemicals.
Acetic Acid 80% has a CAS number of 64-19-7.
The amount of Acetic Acid 80% in vinegar is relatively small.


Acetic Acid 80%, otherwise known as ethanoic acid, is a simple carboxylic acid that usually forms a liquid at room temperature.
Acetic Acid 80% is most widely used in table vinegar due to the preservative properties it holds and is the chemical responsible for the characteristic vinegar odour.


Acetic Acid 80% also has a wide range of applications in the chemical industry and is used in the synthesis of esters and vinyl acetate. Within a laboratory setting, Acetic Acid 80% is a commonly used solvent.
Acetic Acid 80% is registered under the REACH Regulation and is manufactured in and / or imported to the European Economic Area, at ≥ 1 000 000 tonnes per annum.


Acetic Acid 80% is a product of the oxidation of ethanol and of the destructive distillation of wood.
Acetic Acid 80% is used locally, occasionally internally, as a counterirritant and also as a reagent.
Acetic Acid 80% otic (for the ear) is an antibiotic that treats infections caused by bacteria or fungus.


While this is usually the least expensive way of purchasing Acetic Acid 80% we find that more dilute grades such as 90% are more in demand to eliminate most of the solidification problems.
Acetic Acid 80% may sound like it should be in a chemistry lab or science fair rather than in your kitchen pantry.


However, Acetic Acid 80% is actually the main compound found in vinegar and is responsible for both its unique flavor and acidity.
Not only that, but Acetic Acid 80%’s also believed to contribute to many of the health benefits of apple cider vinegar due to its potent medicinal properties.
Acetic Acid 80%, also known as ethanoic acid, is a chemical compound found in many different products.


Acetic Acid 80%’s perhaps most well-known as the main component of vinegar, apart from water, and is thought to supply ingredients like apple cider vinegar with many of their health-promoting properties.
Chemically speaking, the Acetic Acid 80% formula is C2H4O2, which can also be written as CH3COOH or CH3CO2H.


Because of the presence of a carbon atom in the Acetic Acid 80% structure, it’s considered an organic compound.
The Acetic Acid 80% density is about 1.05 grams/cm³; compared to other compounds like nitric acid, sulfuric acid or formic acid, the density of Acetic Acid 80% is quite a bit lower.


Conversely, the Acetic Acid 80% melting point is significantly higher than many other acids, and the Acetic Acid 80% molar mass and Acetic Acid 80% boiling point tend to fall right about in the middle.
Acetic Acid 80% which is also known as methane carboxylic acid and ethanoic acid is basically a clear, colorless liquid, which has a strong and pungent smell.


Since Acetic Acid 80% has a carbon atom in its chemical formula, it is an organic compound and it comes with a chemical formula CH3COOH.
Interestingly, the word ‘acetic’ is derived from a Latin word called ‘acetum’ meaning ‘vinegar’.
Vinegar is the dilute form of Acetic Acid 80% and is the most common chemical substance among people.


Acetic Acid 80% is a main component of vinegar and also gives vinegar its characteristic smell.
Acetic Acid 80% (CH3COOH), also called ethanoic acid, is the most important of the carboxylic acids.
A dilute (approximately 5 percent by volume) solution of Acetic Acid 80% produced by fermentation and oxidation of natural carbohydrates is called vinegar; a salt, ester, or acylal of Acetic Acid 80% is called acetate.


Moving on, when Acetic Acid 80% or ethanoic acid is undiluted it is termed glacial Acetic Acid 80%.
Acetic Acid 80% is a weak acid but when it is in concentrated form, this acid is corrosive and can cause some damage to the skin.
Acetic Acid 80% appears as a clear colorless liquid with a strong odor of vinegar.


Flash point of Acetic Acid 80% is 104 °F.
Density of Acetic Acid 80% is 8.8 lb / gal.
Acetic Acid 80% is corrosive to metals and tissue.


Acetic Acid 80%, solution, more than 10% but not more than 80% acid appears as a colorless aqueous solution.
Acetic Acid 80% smells like vinegar.
Acetic Acid 80% is corrosive to metals and tissue.


Acetic Acid 80%, solution, more than 80% acid is a clear colorless aqueous solution with a pungent odor.
Acetic Acid 80% is faintly pink wet crystals with an odor of vinegar.
Acetic Acid 80% is a simple monocarboxylic acid containing two carbons.


Acetic Acid 80% has a role as a protic solvent, a food acidity regulator, an antimicrobial food preservative and a Daphnia magna metabolite.
Acetic Acid 80% is a conjugate acid of an acetate.
Acetic Acid 80% is a product of the oxidation of ethanol and of the destructive distillation of wood.


Acetic Acid 80% is a metabolite found in or produced by Escherichia coli.
Acetic Acid 80% is a natural product found in Camellia sinensis, Microchloropsis, and other organisms with data available.
Acetic Acid 80% is a synthetic carboxylic acid with antibacterial and antifungal properties.


Although its mechanism of action is not fully known, undissociated Acetic Acid 80% may enhance lipid solubility allowing increased fatty acid accumulation on the cell membrane or in other cell wall structures.
Acetic Acid 80% is one of the simplest carboxylic acids.


Acetic Acid 80% is an important chemical reagent and industrial chemical that is used in the production of plastic soft drink bottles, photographic film; and polyvinyl acetate for wood glue, as well as many synthetic fibres and fabrics.
Acetic Acid 80% can be very corrosive, depending on the concentration.


Acetic Acid 80% is one ingredient of cigarette.
The acetyl group, derived from Acetic Acid 80%, is fundamental to the biochemistry of virtually all forms of life.
When bound to coenzyme A it is central to the metabolism of carbohydrates and fats.


However, the concentration of free Acetic Acid 80% in cells is kept at a low level to avoid disrupting the control of the pH of the cell contents.
Acetic Acid 80% is produced and excreted by certain bacteria, notably the Acetobacter genus and Clostridium acetobutylicum.
These bacteria are found universally in foodstuffs, water, and soil, and Acetic Acid 80% is produced naturally as fruits and some other foods spoil.


Acetic Acid 80% is also a component of the vaginal lubrication of humans and other primates, where it appears to serve as a mild antibacterial agent.
Acetic Acid 80% /əˈsiːtɪk/, systematically named ethanoic acid /ˌɛθəˈnoʊɪk/, is an acidic, colourless liquid and organic compound with the chemical formula CH3COOH (also written as CH3CO2H, C2H4O2, or HC2H3O2).


Vinegar is at least 4% Acetic Acid 80% by volume, making Acetic Acid 80% the main component of vinegar apart from water.
Acetic Acid 80% has been used, as a component of vinegar, throughout history from at least the third century BC.
Acetic Acid 80% is the second simplest carboxylic acid (after formic acid).


Acetic Acid 80% is an important chemical reagent and industrial chemical across various fields, used primarily in the production of cellulose acetate for photographic film, polyvinyl acetate for wood glue, and synthetic fibres and fabrics.
Acetic Acid 80% is a very important organic compound in the day-to-day lives of humans.


The desirable solvent properties of Acetic Acid 80%, along with its ability to form miscible mixtures with both polar and non-polar compounds, make it a very important industrial solvent.
Acetic Acid 80% is also known as ethanoic acid, ethylic acid, vinegar acid, and methane carboxylic acid.


Acetic Acid 80% is a byproduct of fermentation, and gives vinegar its characteristic odor.
Vinegar is about 4-6% Acetic Acid 80% in water.
More concentrated solutions can be found in laboratory use, and pure Acetic Acid 80% containing only traces of water is known as glacial Acetic Acid 80%.


Dilute solutions like vinegar can contact skin with no harm, but more concentrated solutions will burn the skin.
Glacial Acetic Acid 80% can cause skin burns and permanent eye damage, and will corrode metal.
Acetic Acid 80% is an organic compound with the formula CH3COOH.


Acetic Acid 80% is a carboxylic acid consisting of a methyl group that is attached to a carboxyl functional group.
The systematic IUPAC name of Acetic Acid 80% is ethanoic acid and its chemical formula can also be written as C2H4O2.
Vinegar is a solution of Acetic Acid 80% in water and contains between 5% to 20% ethanoic acid by volume.


The pungent smell and the sour taste are characteristic of the Acetic Acid 80% present in it.
An undiluted solution of Acetic Acid 80% is commonly referred to as glacial Acetic Acid 80%.
Acetic Acid 80% forms crystals which appear like ice at temperatures below 16.6oC.


Acetic Acid 80% (CH3COOH), the most important of the carboxylic acids.
A dilute (approximately 5 percent by volume) solution of Acetic Acid 80% produced by fermentation and oxidation of natural carbohydrates is called vinegar; a salt, ester, or acylal of Acetic Acid 80% is called acetate.


Industrially, Acetic Acid 80% is used in the preparation of metal acetates, used in some printing processes; vinyl acetate, employed in the production of plastics; cellulose acetate, used in making photographic films and textiles; and volatile organic esters (such as ethyl and butyl acetates), widely used as solvents for resins, paints, and lacquers.


Biologically, Acetic Acid 80% is an important metabolic intermediate, and it occurs naturally in body fluids and in plant juices.
Acetic Acid 80% has been prepared on an industrial scale by air oxidation of acetaldehyde, by oxidation of ethanol (ethyl alcohol), and by oxidation of butane and butene.


Today Acetic Acid 80% is manufactured by a process developed by the chemical company Monsanto in the 1960s; it involves a rhodium-iodine catalyzed carbonylation of methanol (methyl alcohol).
Pure Acetic Acid 80%, often called glacial Acetic Acid 80%, is a corrosive, colourless liquid (boiling point 117.9 °C [244.2 °F]; melting point 16.6 °C [61.9 °F]) that is completely miscible with water.


Acetic Acid 80% is a clear, colorless, organic liquid with a pungent odor similar to household vinegar.
Acetic Acid 80% or glacial Acetic Acid 80%, also known as ethanoic acid, is an organic compound with the chemical formula CH3COOH.
Pure glacial Acetic Acid 80% (anhydrous Acetic Acid 80%) is a colorless, hygroscopic liquid with a strong pungent odor.


The freezing point is 16.6°C, and Acetic Acid 80% turns into colorless crystals after solidification.
Acetic Acid 80% is an organic monobasic acid and can be miscible with water in any proportion.
Acetic Acid 80% is particularly corrosive to metals.


Acetic Acid 80% is widely found in nature, such as in the fermentation metabolism and putrefaction products of various glacial Acetic Acid 80% bacteria.
Acetic Acid 80% is also the main component of vinegar.
Moreover, glacial Acetic Acid 80% always plays an important role in many chemical reactions.


For example, Acetic Acid 80% can undergo displacement reactions with metals such as iron, zinc, and copper to generate metal acetates and hydrogen.
In addition, Acetic Acid 80% can react with alkalis, alkaline oxides, salts and certain metal oxides.
Acetic Acid 80% is an organic chemical substance, it is a colourless liquid with a very distinctive odour.


One of its most common uses is in the composition of vinegar, although Acetic Acid 80% is also used in cosmetics and pharmaceuticals, in the food, textile and chemical industries.
On an industrial level, Acetic Acid 80% is produced through the carbonylation of methanol and is used as a raw material for the production of different compounds.


Acetic Acid 80% can also be obtained through the food industry by the acetic fermentation process of ethanol, or more commonly explained, through alcoholic fermentation and with the distillation of wood.
Pure Acetic Acid 80% or glacial Acetic Acid 80%, also known as CH3COOH, is a liquid that can be harmful to our health due to its irritating and corrosive properties and can cause severe skin, eye and digestive tract irritation.


However, thanks to its combination with different substances, Acetic Acid 80% is possible to obtain everyday products that may be familiar to everyone, such as vinegar.
Vinegar is a hygroscopic substance, i.e. it can absorb moisture from its surroundings.


Therefore, when it is mixed with water, there is a very significant reduction in its volume.
On the other hand, when Acetic Acid 80% 100 % is exposed to low temperatures, the surface, also known as acetic essence, crystallises and forms ice-like crystals at the top.


Due to the chemical structure of Acetic Acid 80%, it has a very high boiling point.
Furthermore, it is worth noting that Acetic Acid 80%, being a carboxylic acid, has the ability to dissociate, but only slightly, as it is a weak acid [FC1].
Moreover, thanks to this ability to dissociate, Acetic Acid 80% conducts electricity effectively.


Acetic Acid 80% is an organic compound with the chemical formula CH3COOH.
Acetic Acid 80% is an organic monobasic acid and is the main component of vinegar.
Pure anhydrous Acetic Acid 80% (glacial Acetic Acid 80%) is a colorless, hygroscopic liquid with a freezing point of 16.6 ℃ (62 ℉).


After solidification, Acetic Acid 80% becomes a colorless crystal.
Acetic Acid 80% or ethanoic acid is a colourless liquid organic compound with the molecular formula CH3COOH.
When Acetic Acid 80% is dissolved in water, it is termed glacial Acetic Acid 80%.


Vinegar is no less than 4 per cent Acetic Acid 80% by volume, aside from water, allowing Acetic Acid 80% to be the main ingredient of vinegar.
Acetic Acid 80% is produced primarily as a precursor to polyvinyl acetate and cellulose acetate, in addition to household vinegar.
Acetic Acid 80% is a weak acid since the solution dissociates only slightly.


But concentrated Acetic Acid 80% is corrosive and can damage the flesh.
The second simplest carboxylic acid is Acetic Acid 80% (after formic acid).
Acetic Acid 80% consists of a methyl group to which a carboxyl group is bound.


Acetic Acid 80% is a colourless liquid organic compound with pungent characteristic odour.
Acetic Acid 80% is an acid that occurs naturally.
Acetic Acid 80% can also be produced synthetically either by acetylene or by using methanol.


Acetic Acid 80% is considered as a natural preservative for food products.
Acetic Acid 80% has been used for hundreds of years as a preservative (vinegar, French for "sour wine").
If during the fermentation of grapes or other fruits, oxygen is allowed into the container, then bacteria convert the ethanol present into Acetic Acid 80% causing the wine to turn sour.


Acetic Acid 80% may be synthetically produced using methanol carbonylation, acetaldehyde oxidation, or butane/naphtha oxidation.
Acetic Acid 80% is termed "glacial", and is completely miscible with water.
Acetic Acid 80% is the main component of vinegar.


Acetic Acid 80% appears as a clear, colorless liquid with a distinctive sour taste and pungent smell.
Acetic Acid 80% is used as a preservative, acidulant, and flavoring agent in mayonnaise and pickles.
Though Acetic Acid 80%’s considered safe, some are convinced it has potentially dangerous health effects.


Acetic Acid 80% systematically named ethanoic acid, is a colourless liquid organic compound with the chemical formula CH3COOH (also written as CH3CO2H or C2H4O2).
When undiluted, Acetic Acid 80% is sometimes called glacial Acetic Acid 80%.


Acetic Acid 80% is an organic compound belonging to the weak carboxylic acids.
The set of properties of Acetic Acid 80% classifies it as a broad-spectrum reagent and allows it to be used in a wide variety of industrial fields: from pharmacology and cosmetology to the chemical and food industries.


Acetic Acid 80% is one of the most common acids used in the food industry and household.
Acetic Acid 80% is a colorless, pungent, odorless liquid that miscible mixes with water to form solutions of varying concentrations.
Due to its ability to crystallize at an already positive temperature, Acetic Acid 80% is also known as “glacial”.


Acetic Acid 80% is a synthetic carboxylic acid with antibacterial and antifungal properties.
Although Acetic Acid 80%'s mechanism of action is not fully known, undissociated Acetic Acid 80% may enhance lipid solubility allowing increased fatty acid accumulation on the cell membrane or in other cell wall structures.


Acetic Acid 80%, as a weak acid, can inhibit carbohydrate metabolism resulting in subsequent death of the organism.
Acetic Acid 80% is present in most fruits.
Acetic Acid 80% is produced by bacterial fermentation and thus present in all fermented products.


In mayonnaise, Acetic Acid 80% is added to increase the inactivation of Salmonella.
Acetic Acid 80%, known also as ethanoic acid, is a weak acid that is commonly used as a food preservative and flavoring agent.
Acetic Acid 80%'s chemical formula is CH3COOH, and its molecular weight is 60.05 g/mol.


Acetic Acid 80% is a clear, colorless liquid that has a pungent odor and a sour taste.
Acetic Acid 80% is miscible with water and most common organic solvents.
Acetic Acid 80% is produced naturally in most organisms as a byproduct of metabolism.


Acetic Acid 80% is also a major component of vinegar, which is a solution of Acetic Acid 80% and water that occurs naturally when ethanol in fermented fruit juices undergoes oxidation by Acetic Acid 80% bacteria.
The production of vinegar has been an ancient practice of food preservation and flavoring that dates back to ancient times.


Acetic Acid 80% has several applications outside of the food industry.
Acetic Acid 80% is used as a solvent in the production of various chemicals and is an important intermediate in the manufacture of polymers, fibers, and pharmaceuticals.


Acetic Acid 80% is classified as a weak acid because it only partially ionizes in water to produce hydrogen ions (H+) and acetate ions (CH3COO-).
The pH of a 1% solution of Acetic Acid 80% is approximately 2.4, which means it is acidic but relatively less acidic than some stronger acids like hydrochloric acid or sulfuric acid.


Acetic Acid 80% is both naturally occurring and synthetic.
Natural sources include fermentation and bacteria.
In fermentation, Acetic Acid 80% is produced when yeast breaks down sugar in the absence of oxygen.


Bacteria produce Acetic Acid 80% when they oxidize ethanol.
Synthetic Acetic Acid 80% is made by reacting methanol with carbon monoxide in the presence of a catalyst.
Acetic Acid 80% has a strong odor and taste.


The odor of Acetic Acid 80% is similar to that of vinegar and the taste is sour.
Acetic Acid 80% is not considered toxic in small quantities and is generally recognized as safe by the US Food and Drug Administration (FDA) when used in accordance with good manufacturing practices.


The safety of Acetic Acid 80% depends on its concentration, with higher concentrations being more corrosive to skin and eyes.
In summary, Acetic Acid 80% is a weak acid that is commonly used as a food preservative and flavoring agent.
Another important use of Acetic Acid 80% is as a chemical intermediate.


Lastly, Acetic Acid 80% is an important ingredient in the winemaking process.
In this case, Acetic Acid 80% is produced naturally as a byproduct of the wine fermentation process.
However, if Acetic Acid 80% levels are too high, it can cause a wine to taste or smell like vinegar, which is undesirable.


To avoid this, winemakers use sulfites to inhibit the growth of Acetic Acid 80% bacteria in the wine.
Acetic Acid 80% is also an effective cleaning agent, especially when it comes to eliminating stubborn stains or mineral build-up due to hard water.
Acetic Acid 80%'s acidic nature helps to loosen dirt, grime, and other impurities from surfaces.


Acetic Acid 80% is found naturally in many foods, including vinegar and fermented products.
However, when used as an additive, Acetic Acid 80% is typically produced synthetically.
Acetic Acid 80% is generally recognized as safe (GRAS) when used in accordance with good manufacturing practices.


Overall, Acetic Acid 80% is considered a safe food additive when used within recommended limits.
As with any food additive, Acetic Acid 80% is essential to follow regulations and guidelines set by relevant authorities.



USES and APPLICATIONS of ACETIC ACID 80%:
In the home, diluted Acetic Acid 80% is often used in descaling agents.
In the food industry, Acetic Acid 80% is used under the food additive (EU number E260) as an acidity regulator and as a condiment.
Acetic Acid 80% is widely approved for usage as a food additive.


Acetic Acid 80% 80% is an essential chemical with a wide range of applications.
Acetic Acid 80% is a strong organic acid, also known as ethanoic or vinegar acid, and is used in a variety of industries, from the production of paints and adhesives to the food and pharmaceutical industries.


Acetic Acid 80% is an efficient solvent and a condensing agent in chemical synthesis processes.
Acetic Acid 80% is also used in the production of vinyl acetate, a key ingredient in polymer manufacturing.
Acetic Acid 80% is a highly concentrated solution, ideal for professionals and experienced users.


With Acetic Acid 80% you can remove stubborn limescale, green deposits and other types of pollution.
In general, for most applications Acetic Acid 80% should first be diluted with water.
For a ready-made solution of Acetic Acid 80% that you can use immediately for your cleaning work, you can also purchase cleaning vinegar .


Acetic Acid 80% is most commonly used in the production of vinyl acetate monomer (VAM), in ester production and for the breeding of bees.
As a natural acid, Acetic Acid 80% offers a wide range of possible applications: e.g. in cleaning formulations and for decalcification.
In addition, Acetic Acid 80% is commonly used as a biogenic herbicide, although commercial use as a herbicide is not permitted on enclosed areas.


Applications of Acetic Acid 80%: Adhesives/sealants-B&C, Agriculture intermediates, Apparel, Architectural coatings, Automotive protective coatings, Building materials, Commercial printing inks, Construction chemicals, Decorative interiors, Fertilizer, Food ingredients, Food preservatives, Formulators, Hard surface care, Industrial cleaners, Institutional cleaners.


Applications of Acetic Acid 80%:Intermediates, Oil or gas processing, Other-food chemicals, Other-transportation, Packaging components non-food contact, Paints & coatings, Pharmaceutical chemicals, Process additives, Refining, Specialty chemicals, Starting material, and Water treatment industrial.


Acetic Acid 80% is a raw material used for the production of many downstream products.
For applications in drugs, foods, or feeds, Eastman provides Acetic Acid 80% in grades appropriate for these regulated uses.
Acetic Acid 80% is most commonly found in vinegar, which is used in recipes ranging from salad dressings to condiments, soups and sauces.


Vinegar is also used as a food preservative and pickling agent.
Plus, it can even be used to make natural cleaning products, skin toners, bug sprays and more.
Some medications contain Acetic Acid 80%, including those used to treat ear infections.


Some also use Acetic Acid 80% in the treatment of other conditions, including warts, lice and fungal infections, although more research is needed to evaluate its safety and effectiveness.
Acetic Acid 80% is also used by manufacturers to create a variety of different products.


In particular, Acetic Acid 80% is used to make chemical compounds like vinyl acetate monomer as well as perfumes, oral hygiene products, skin care products, inks and dyes.
Release to the environment of Acetic Acid 80% can occur from industrial use: industrial abrasion processing with low release rate (e.g. cutting of textile, cutting, machining or grinding of metal).


Other release to the environment of Acetic Acid 80% is likely to occur from: indoor use in long-life materials with low release rate (e.g. flooring, furniture, toys, construction materials, curtains, foot-wear, leather products, paper and cardboard products, electronic equipment) and outdoor use in long-life materials with low release rate (e.g. metal, wooden and plastic construction and building materials).


Acetic Acid 80% can be found in products with material based on: paper (e.g. tissues, feminine hygiene products, nappies, books, magazines, wallpaper), leather (e.g. gloves, shoes, purses, furniture), fabrics, textiles and apparel (e.g. clothing, mattress, curtains or carpets, textile toys) and wood (e.g. floors, furniture, toys).


Acetic Acid 80% is used in the following products: laboratory chemicals, pH regulators and water treatment products, water treatment chemicals, plant protection products and washing & cleaning products.
Acetic Acid 80% is used in the following areas: formulation of mixtures and/or re-packaging.


Acetic Acid 80% is used for the manufacture of: chemicals.
Other release to the environment of Acetic Acid 80% is likely to occur from: outdoor use and indoor use (e.g. machine wash liquids/detergents, automotive care products, paints and coating or adhesives, fragrances and air fresheners).


Acetic Acid 80% is used in the following products: coating products, perfumes and fragrances, paper chemicals and dyes, textile treatment products and dyes, metal surface treatment products, non-metal-surface treatment products and polymers.
Acetic Acid 80% is used by consumers, in articles, by professional workers (widespread uses), in formulation or re-packing, at industrial sites and in manufacturing.


Release to the environment of Acetic Acid 80% can occur from industrial use: formulation of mixtures, formulation in materials, manufacturing of the substance, in processing aids at industrial sites, as an intermediate step in further manufacturing of another substance (use of intermediates), as processing aid, for thermoplastic manufacture, as processing aid, of substances in closed systems with minimal release and in the production of articles.


Acetic Acid 80% is used in the following products: laboratory chemicals, pH regulators and water treatment products, oil and gas exploration or production products, water treatment chemicals, washing & cleaning products, polymers and coating products.
Acetic Acid 80% is used in the following areas: mining and formulation of mixtures and/or re-packaging.


Acetic Acid 80% is used for the manufacture of: chemicals, textile, leather or fur, wood and wood products and pulp, paper and paper products.
Release to the environment of Acetic Acid 80% can occur from industrial use: in processing aids at industrial sites, as an intermediate step in further manufacturing of another substance (use of intermediates) and manufacturing of the substance.


Release to the environment of Acetic Acid 80% can occur from industrial use: manufacturing of the substance, in processing aids at industrial sites, as an intermediate step in further manufacturing of another substance (use of intermediates), formulation of mixtures, formulation in materials, in the production of articles, as processing aid, for thermoplastic manufacture, as processing aid and of substances in closed systems with minimal release.


Acetic Acid 80% is used in the following products: coating products, washing & cleaning products, air care products, lubricants and greases, fillers, putties, plasters, modelling clay, anti-freeze products, fertilisers, plant protection products, finger paints, biocides (e.g. disinfectants, pest control products), welding & soldering products and textile treatment products and dyes.


Other release to the environment of Acetic Acid 80% is likely to occur from: outdoor use, indoor use (e.g. machine wash liquids/detergents, automotive care products, paints and coating or adhesives, fragrances and air fresheners) and indoor use in close systems with minimal release (e.g. cooling liquids in refrigerators, oil-based electric heaters).


Industrially, Acetic Acid 80% is used in the preparation of metal acetates, used in some printing processes; vinyl acetate, employed in the production of plastics; cellulose acetate, used in making photographic films and textiles; and volatile organic esters (such as ethyl and butyl acetates), widely used as solvents for resins, paints, and lacquers.


Biologically, Acetic Acid 80% is an important metabolic intermediate, and it occurs naturally in body fluids and in plant juices.
Aside from its uses as a natural preservative and common ingredient in a variety of products, Acetic Acid 80% has also been associated with several impressive health benefits.


In addition to its potent anti-bacterial properties, Acetic Acid 80% is also thought to reduce blood sugar levels, promote weight loss, alleviate inflammation and control blood pressure.
As chemical distributors, the purposes for which this type of Acetic Acid 80% is processed are varied.


As mentioned above, Acetic Acid 80% can be found in many grocery shops as white vinegar.
In such products, Acetic Acid 80% cannot be found in its pure form, but only in small quantities.
Acetic Acid 80% is also present in foods such as canned and pickled foods, cheese and dairy products, sauces or prepared salads.


Acetic Acid 80% is also commonly used in the pharmaceutical, cosmetic and industrial industries both to produce other substances and to regulate their properties, especially with regards to their pH.
Due to its strong odour, one of its other main uses is in cosmetics as a regulator in the aroma of fragrances, i.e. Acetic Acid 80% achieves a balance between sweet smells in particular.


In the textile industry, Acetic Acid 80% is used to dye fabrics and produce fabrics such as viscose or latex.
In the chemical industry, Acetic Acid 80% is used in the production of cleaning products and, in the pharmaceutical industry, in supplements and some medicines, as it is capable of stabilising blood pressure and reducing blood sugar levels.


Acetic Acid 80% is also a common ingredient in ointments.
In households diluted Acetic Acid 80% is often used as a cleaning agent. In the food industry Acetic Acid 80% is used as an acidity regulator.
Acetic Acid 80% is used to make other chemicals, as a food additive, and in petroleum production.


Acetic Acid 80% is used locally, occasionally internally, as a counterirritant and also as a reagent.
Acetic Acid 80% otic (for the ear) is an antibiotic that treats infections caused by bacteria or fungus.
In households, diluted Acetic Acid 80% is often used in descaling agents.


In the food industry, Acetic Acid 80% is controlled by the food additive code E260 as an acidity regulator and as a condiment.
In biochemistry, the acetyl group, derived from Acetic Acid 80%, is fundamental to all forms of life.
When bound to coenzyme A, Acetic Acid 80% is central to the metabolism of carbohydrates and fats.


The global demand for Acetic Acid 80% is about 6.5 million metric tonnes per year (t/a), manufactured from methanol.
Acetic Acid 80%'s production and subsequent industrial use poses health hazards to workers, including incidental skin damage and chronic respiratory injuries from inhalation.


Acetic Acid 80% is a chemical reagent for the production of chemical compounds.
The largest single use of Acetic Acid 80% is in the production of vinyl acetate monomer, closely followed by acetic anhydride and ester production.
The volume of Acetic Acid 80% used in vinegar is comparatively small.


In the field of analytical chemistry, glacial Acetic Acid 80% is widely used in order to estimate substances that are weakly alkaline.
Acetic Acid 80% has a wide range of applications as a polar, protic solvent.
Acetic Acid 80% is used as an antiseptic due to its antibacterial qualities


The manufacture of rayon fiber involves the use of Acetic Acid 80%.
Medically, Acetic Acid 80% has been employed to treat cancer by its direct injection into the tumour.
Being the major constituent of vinegar, Acetic Acid 80% finds use in the pickling of many vegetables.


The manufacture of rubber involves the use of Acetic Acid 80%.
Acetic Acid 80% is also used in the manufacture of various perfumes.
Acetic Acid 80% is widely used in the production of VAM (vinyl acetate monomer).


When two molecules of Acetic Acid 80% undergo a condensation reaction together, the product formed is acetic anhydride.
Acetic Acid 80% is widely used in the industrial preparation of dimethyl terephthalate (DMT).
Acetic Acid 80% is used in the manufacture of acetic anhydride, cellulose acetate, vinyl acetate monomer, acetic esters, chlorAcetic Acid 80%, plastics, dyes, insecticides, photographic chemicals, and rubber.


Other commercial uses of Acetic Acid 80% include the manufacture of vitamins, antibiotics, hormones, and organic chemicals, and as a food additive (acidulant).
Acetic Acid 80% is also used in various textile printing processes.
Acetic Acid 80% is the main component of vinegar, which contains 4 to 18% Acetic Acid 80%.


Acetic Acid 80% is used as a food preservative and food additive (known as E260).
Acetic Acid 80% is used as a raw material and solvent in the production of other chemical products, in oil and gas production, and in the food and pharmaceutical industries.


Large quantities of Acetic Acid 80% are used to make products such as ink for textile printing, dyes, photographic chemicals, pesticides, pharmaceuticals, rubber and plastics.
Acetic Acid 80% is also used in some household cleaning products to remove lime scale.


In foods, Acetic Acid 80% is used for its antibacterial properties, as an acidity stabiliser, diluting colours, as a flavouring agent and for inhibiting mould growth in bread.
Derivatives of Acetic Acid 80% are used as food additives and preservatives, as well as in the production of various chemicals and materials.


In brewing, Acetic Acid 80% is used to reduce excess losses of carbohydrate from the germinated barley and to compensate for production variations, so producing a consistent quality beer.
Acetic Acid 80% can be found in beer, bread, cheese, chutney, horseradish cream, pickles, salad cream, brown sauce, fruit sauce, mint sauce and jelly and tinned baby food, sardines and tomatoes.


Acetic Acid 80% is often used as table vinegar.
Acetic Acid 80% is also used directly as a condiment, and in the pickling of vegetables and other foods.
Acetic Acid 80% is used as the main component in the subsequent synthesis in the process of food and pharmaceutical production.


Food additive Acetic Acid 80% is widely used in marinating, canning, making mayonnaise and sauces and other foods.
In one of Acetic Acid 80%'s most common form, vinegar is also used directly as a condiment, and in the pickling of vegetables and other foods to preserve food against bacteria and fungi.


In brewing, Acetic Acid 80% is used to reduce excess losses of carbohydrate from the germinated barley and to compensate for production variations, so producing a consistent quality beer.
When used as food additive, Acetic Acid 80% has a E number 260.


Acetic Acid 80% can be found in beer, bread, cheese, chutney, horseradish cream, pickles, salad cream, brown sauce, fruit sauce, mint sauce and jelly and tinned baby food, sardines and tomatoes.
Acetic Acid 80% is approved to use as food addictive in EU and generally recognized as safe food substance in the US.


In addition to vinegar, Acetic Acid 80% is used as a food additive and preservative in a variety of other foods, including baked goods, processed meats, cheeses, and condiments.
Many pickled foods, like pickles and sauerkraut, also contain Acetic Acid 80% as a natural byproduct of the fermentation process.


Acetic Acid 80% is also used in the production of various food ingredients, including salts, esters, and anhydrides.
These derivatives of Acetic Acid 80% are used as preservatives, flavorings, and emulsifiers in processed foods.
Some examples of these derivatives include sodium acetate, ethyl acetate, and acetic anhydride.


Acetic Acid 80% is also used in the production of various adhesives, coatings, and inks, and is used to produce cellulose acetate, which is used in photographic films and other applications.
Acetic Acid 80% is found naturally in many foods and is also produced synthetically for a variety of industrial applications.


Acetic Acid 80% is one of the simplest carboxylic acid.
It has a variety of uses, ranging from food and medical to industrial.
As mentioned earlier, Acetic Acid 80% is primarily found in vinegar.


Acetic Acid 80%'s also used as food additive (E number E260) for regulating acidity and as a preservative.
Acetic Acid 80% is also essential in the pickling process, which involves preserving vegetables or fruits (such as cucumbers, beets, or watermelon rind) in vinegar.


Acetic Acid 80% helps to prevent the growth of harmful bacteria and preserves the vegetables or fruits' natural color, flavor, and texture.
Pickling is a common technique used to preserve foods, especially in countries with long winter seasons where fresh produce is not available.
Acetic Acid 80% can also be used to produce synthetic fabrics that resemble natural ones such as silk, wool or cotton.


Acetic Acid 80% is used in the production of a wide range of chemicals and materials, such as vinyl acetate monomer (VAM), cellulose acetate, and acetic anhydride.
These chemicals are used in various industries, including textiles, plastics, coatings, and adhesives.


Acetic Acid 80% can be used to increase the acidity (and lower the pH) of food products as well as improve the organoleptic quality by giving the product an acid flavor, such as salt and vinegar chips.
Acetic Acid 80% is also a popular preservative as it stops bacterial growth in dressings, sauces, cheese, and pickles.


Acetic Acid 80%/vinegar is used to pickle foods, which is a type of preservation method. When used with baking soda, Acetic Acid 80% also works as a chemical leavening agent.
Besides food, Acetic Acid 80% has been used in medicine, such as in ear drops, and a number of industrial processes.


Acetic Acid 80% is used to make cellulose acetate and polyvinyl acetate and glacial Acetic Acid 80% in particular is frequently used as a solvent.
As mentioned before, Acetic Acid 80% is extensively used as a food preservative.
Acetic Acid 80% makes foods less hospitable to harmful bacteria that can cause food poisoning.


When used in small amounts, Acetic Acid 80% can effectively extend the shelf life of food items.
Furthermore, Acetic Acid 80% can also be added to pickling liquid to help maintain the pickled product's acidity level, thereby making it last longer.
Another popular application of Acetic Acid 80% is as a natural food flavour enhancer.


Along with improving the taste of many processed foods including sauces, dressings, and condiments, Acetic Acid 80% is also used to provide a sour tang to beverages like soda and energy drinks.
Acetic Acid 80% is added in small amounts to these products in order to impart a tart, refreshing taste that many consumers prefer.


Acetic Acid 80% is used in a wide variety of household cleaning products, including all-purpose cleaners, glass cleaners, and bathroom cleaning solutions.
In addition to its use in household cleaners, Acetic Acid 80% is also used as a natural weed killer.
Acetic Acid 80% can be sprayed on weeds in gardens and lawns to kill them without contaminating the soil.


Some environmentally conscious gardeners prefer using vinegar sprays instead of toxic chemical herbicides, as Acetic Acid 80% is considered a more eco-friendly solution.
Some research has also shown that Acetic Acid 80% may have potential health benefits.


For instance, Acetic Acid 80% has been studied for its potential to lower blood sugar levels and improve insulin sensitivity.
In addition, Acetic Acid 80% may help with weight loss by reducing appetite and promoting feelings of fullness.
However, more research is needed to fully understand the potential health benefits of Acetic Acid 80%.


In terms of safety, Acetic Acid 80% should be handled with care.
To summarize, Acetic Acid 80% is a versatile ingredient with numerous applications.
Acetic Acid 80% is commonly used as a food preservative, flavour enhancer, and cleaning agent.


Acetic Acid 80% also has potential health benefits, although further research is needed to confirm these benefits.
As with any chemical, Acetic Acid 80% should be handled with care and stored properly to minimize risk of injury or damage to property.
In conclusion, Acetic Acid 80% is a widely-used food ingredient with many applications and benefits.


Acetic Acid 80% is a natural substance that is safe when used appropriately.
Whether you're using it in the kitchen or for cleaning purposes, Acetic Acid 80% is a versatile and effective solution that has been relied upon for centuries.
Acetic Acid 80% is a versatile and widely-used food ingredient with a range of possible benefits and applications, as well as a few drawbacks.


Understanding the properties and uses of Acetic Acid 80% is essential for anyone working with food or chemicals.
In addition to Acetic Acid 80%, there are other types of acids that are used in food production, such as ascorbic acid (vitamin C), citric acid, and malic acid.
These acids are commonly used as preservatives, stabilizers, flavor enhancers, and acidulants, depending on the specific product formulation.


While each type of acid has its own unique properties, Acetic Acid 80% stands out for its sour taste and pungent aroma.
One of the key applications of Acetic Acid 80% is in the production of vinegar, which is a widely-used condiment that is made by fermenting ethanol and other sugars.


Apple cider vinegar, balsamic vinegar, and white vinegar are some of the most popular vinegar varieties available.
Each type of vinegar has Acetic Acid 80%'s own unique flavor and can be used in a range of recipes, from marinades to salad dressings.
Acidity regulator Acetic Acid 80% is commonly used in food as a preservative and flavoring agent.


Acetic Acid 80% is primarily used to regulate the acidity levels in various food products, including pickles, sauces, dressings, and condiments.
Additionally, acidity regulator Acetic Acid 80% is effective in preventing the growth of bacteria and fungi in food, extending its shelf life.
Acetic Acid 80% is considered safe for consumption when used within the approved limits set by regulatory authorities.


Acetic Acid 80% is commonly used in pickled vegetables, dressings, sauces, and condiments to provide tartness and enhance flavors.
Acetic Acid 80% has been used in food preservation and flavoring for centuries.
Acetic Acid 80% is a commonly used additive in the food industry.


Acetic Acid 80% is a natural acid found in vinegar and is widely used as a food preservative and flavoring agent.
Acetic Acid 80% is known for its sour taste and is often added to various food products such as pickles, sauces, condiments, and dressings to enhance their flavor and extend their shelf life.


As a food preservative, Acetic Acid 80% works by creating an acidic environment that inhibits the growth of bacteria and other microorganisms.
This helps to prevent food spoilage and increase Acetic Acid 80%'s stability.
Acetic Acid 80% also acts as a pH regulator, helping to maintain the desired acidity level in certain foods.


As with any food additive, it is recommended to consume foods containing Acetic Acid 80% in moderation and as part of a balanced diet.
In conclusion, Acetic Acid 80% is a widely used food additive that serves both as a preservative and a flavor enhancer.
Acetic Acid 80% provides a sour taste and helps to extend the shelf life of various food products.


-Acetic Acid 80% with formula CH3COOH or food additive E260 is used:
*food industry – known as additive E260, is involved in the production of dairy products, salads, sauces, dressings, marinades and canned food;
*Pharmaceutical industry – is part of aspirin, phenacetin, other drugs and dietary supplements that stabilize blood pressure and reduce blood sugar;
*textile industry – as a component for the manufacture and dyeing of rayon, latex fabrics;
*cosmetic sphere – used to balance the smell and regulate the characteristics of various compositions;
*chemical industry – production of cleaning and detergents, household chemicals, acetone, synthetic dyes;
*as a solvent for varnishes, latex coagulant;
*as an acetylating agent in organic synthesis;
*salts of Acetic Acid 80% (Fe, Al, Cr, etc.) – mordants for dyeing, etc.


-Breeding of bees:
Acetic Acid 80% fumigation will kill a wide variety of pathogens, such as the causative agents of Cretaceous brood, European foulbrood, Nosema and Amoeba.
Acetic Acid 80% will also eliminate all stages of the wax moth except the pupae.


-Vinyl acetate monomer:
Production of vinyl acetate monomer (VAM), the application consumes approximately 40% to 45% of the world's Acetic Acid 80% production.
The reaction is with ethylene and Acetic Acid 80% with oxygen over a palladium catalyst.


-Ester production:
Acetic Acid 80% esters are used as a solvent in inks, paints and coatings.
Esters include ethyl acetate, n-butyl acetate, isobutyl acetate, and propyl acetate


-Use as a solvent:
Acetic Acid 80% is an excellent polar protic solvent.
Acetic Acid 80% is often used as a recrystallization solvent to purify organic compounds.
Acetic Acid 80% is used as a solvent in the production of terephthalic acid (TPA), a raw material for the production of polyethylene terephthalate (PET).


-Medical use of Acetic Acid 80%:
Acetic Acid 80% injection into a tumor has been used to treat cancer since the 1800s.
Acetic Acid 80% is used as part of cervical cancer screening in many areas in the developing world.

The acid is applied to the cervix and if an area of white appears after about a minute the test is positive.
Acetic Acid 80% is an effective antiseptic when used as a 1% solution, with broad spectrum of activity against streptococci, staphylococci, pseudomonas, enterococci and others.

Acetic Acid 80% may be used to treat skin infections caused by pseudomonas strains resistant to typical antibiotics.
While diluted Acetic Acid 80% is used in iontophoresis, no high quality evidence supports this treatment for rotator cuff disease.
As a treatment for otitis externa, it is on the World Health Organization's List of Essential Medicines.


-Foods uses of Acetic Acid 80%:
Acetic Acid 80% has 349 kcal (1,460 kJ) per 100 g.
Vinegar is typically no less than 4% Acetic Acid 80% by mass.
Legal limits on Acetic Acid 80% content vary by jurisdiction.

Vinegar is used directly as a condiment, and in the pickling of vegetables and other foods.
Table vinegar tends to be more diluted (4% to 8% Acetic Acid 80%), while commercial food pickling employs solutions that are more concentrated.
The proportion of Acetic Acid 80% used worldwide as vinegar is not as large as industrial uses, but it is by far the oldest and best-known application.


-Acetic Acid 80% as a Solvent:
In its liquid state, CH3COOH is a hydrophile (readily dissolves in water) and also a polar, protic solvent.
A mixture of Acetic Acid 80% and water is, in this manner, similar to a mixture of ethanol and water.
Acetic Acid 80% also forms miscible mixtures with hexane, chloroform, and several oils.
However, Acetic Acid 80% does not form miscible mixtures with long-chain alkanes (such as octane).


-Vinyl acetate monomer:
The primary use of Acetic Acid 80% is the production of vinyl acetate monomer (VAM).
In 2008, this application was estimated to consume a third of the world's production of Acetic Acid 80%.

The reaction consists of ethylene and Acetic Acid 80% with oxygen over a palladium catalyst, conducted in the gas phase.
2 H3C−COOH + 2 C2H4 + O2 → 2 H3C−CO−O−CH=CH2 + 2 H2O
Vinyl acetate can be polymerised to polyvinyl acetate or other polymers, which are components in paints and adhesives


-Ester production:
The major esters of Acetic Acid 80% are commonly used as solvents for inks, paints and coatings.
The esters include ethyl acetate, n-butyl acetate, isobutyl acetate, and propyl acetate.

They are typically produced by catalyzed reaction from Acetic Acid 80% and the corresponding alcohol:
CH3COO−H + HO−R → CH3COO−R + H2O, R = general alkyl group
For example, Acetic Acid 80% and ethanol gives ethyl acetate and water.
CH3COO−H + HO−CH2CH3 → CH3COO−CH2CH3 + H2O

Most acetate esters, however, are produced from acetaldehyde using the Tishchenko reaction.
In addition, ether acetates are used as solvents for nitrocellulose, acrylic lacquers, varnish removers, and wood stains.
First, glycol monoethers are produced from ethylene oxide or propylene oxide with alcohol, which are then esterified with Acetic Acid 80%.

The three major products are ethylene glycol monoethyl ether acetate (EEA), ethylene glycol monobutyl ether acetate (EBA), and propylene glycol monomethyl ether acetate (PMA, more commonly known as PGMEA in semiconductor manufacturing processes, where it is used as a resist solvent).
This application consumes about 15% to 20% of worldwide Acetic Acid 80%.
Ether acetates, for example EEA, have been shown to be harmful to human reproduction.


-Acetic anhydride:
The product of the condensation of two molecules of Acetic Acid 80% is acetic anhydride.
The worldwide production of acetic anhydride is a major application, and uses approximately 25% to 30% of the global production of Acetic Acid 80%.
The main process involves dehydration of Acetic Acid 80% to give ketene at 700–750 °C.

Ketene is thereafter reacted with Acetic Acid 80% to obtain the anhydride:
CH3CO2H → CH2=C=O + H2O
CH3CO2H + CH2=C=O → (CH3CO)2O

Acetic anhydride is an acetylation agent.
As such, Acetic Acid 80%'s major application is for cellulose acetate, a synthetic textile also used for photographic film.
Acetic anhydride is also a reagent for the production of heroin and other compounds.


-Use as solvent:
As a polar protic solvent, Acetic Acid 80% is frequently used for recrystallization to purify organic compounds.
Acetic Acid 80% is used as a solvent in the production of terephthalic acid (TPA), the raw material for polyethylene terephthalate (PET).
In 2006, about 20% of Acetic Acid 80% was used for TPA production.

Acetic Acid 80% is often used as a solvent for reactions involving carbocations, such as Friedel-Crafts alkylation.
For example, one stage in the commercial manufacture of synthetic camphor involves a Wagner-Meerwein rearrangement of camphene to isobornyl acetate; here Acetic Acid 80% acts both as a solvent and as a nucleophile to trap the rearranged carbocation.


-Vinegar:
The vinegar is usually 4-18 wt.% Acetic Acid 80%.
Acetic Acid 80% is used directly as a seasoning and marinade of vegetables and other food products.
Table vinegar is used more often more diluted (4% to 8% Acetic Acid 80%), while a more concentrated solution is used for pickling in commercial foods.


-Industrial Use:
Acetic Acid 80% is used in many industrial processes for the production of substrates and it is often used as a chemical reagent for the production of a number of chemical compounds like acetic anhydride, ester, vinyl acetate monomer, vinegar, and many other polymeric materials.
Acetic Acid 80% is also used to purify organic compounds as it can be used as a solvent for recrystallization.


-Industrial applications of Acetic Acid 80%:
As one of the important organic acids, Acetic Acid 80% is mainly used in the synthesis of vinyl acetate, cellulose acetate, acetic anhydride, acetate, metal acetate and halogenated Acetic Acid 80%.

Glacial Acetic Acid 80% is also an important raw material for pharmaceuticals, dyes, pesticides and other organic synthesis.
In addition, Acetic Acid 80% is also widely used in the manufacture of photographic medicines, cellulose acetate, fabric printing and dyeing, and the rubber industry.


-Food applications of Acetic Acid 80%:
In the food industry, Acetic Acid 80% is generally used as an acidulant, flavor enhancer and spice manufacturing.

*Synthetic vinegar:
Dilute Acetic Acid 80% to 4-5% with water, add various flavoring agents, the flavor is similar to alcohol vinegar, the production time is short, and the price is cheap.

As a sour agent, glacial Acetic Acid 80% can be used in compound seasonings, prepared vinegar, canned food, jelly and cheese, and used in moderation according to production needs.
Acetic Acid 80% can also be used as a flavor enhancer, and the recommended dosage is 0.1-0.3 g/kg.


-Medical Use:
Acetic Acid 80% has a lot of uses in the medical field.
The most important uses here are that Acetic Acid 80% can be used as an antiseptic against pseudomonas, enterococci, streptococci, staphylococci, and others.
Acetic Acid 80% is also used in cervical cancer screening and for the treatment of infections.
Further, Acetic Acid 80% is used as an agent to lyse red blood cells before white blood cells are examined.
Vinegar has also been said to reduce high concentrations of blood sugar.


-Important and Popular Uses of Acetic Acid 80%:
There are many uses of Acetic Acid 80%.
So, in addition to being treated just as a food preservative (vinegar), the acid is used in many areas and instances.

Some top and important uses include:
*Industrial Use
*Medicinal Uses
*Household
*Food Industry


-Food Industry:
In the food industry, Acetic Acid 80% finds its use most commonly in commercial pickling operations, and in condiments like mayonnaise, mustard, and ketchup.
Acetic Acid 80% is also used for seasoning various food items like salads etc.
Additionally, vinegar can react with alkaline ingredients like baking soda and when that happens it produces a gas that helps to make baked goods become.


-Household Uses:
Acetic Acid 80% which is a dilute solution is used extensively as vinegar.
And as we are familiar, vinegar is widely used for cleaning, laundry, cooking, and many other household uses.

Farmers usually spray Acetic Acid 80% on livestock silage to counter bacterial and fungal growth.
Apart from these, Acetic Acid 80% is used for the manufacture of inks and dyes and it is also used in making perfumes.
Acetic Acid 80% is also involved in the manufacturing of rubber and plastic industries.



USES AND BENEFITS OF ACETIC ACID 80%
One of the most common ways consumers may come into contact with Acetic Acid 80% is in the form of household vinegar, which is naturally made from fermentable sources such as wine, potatoes, apples, grapes, berries and grains.

Vinegar is a clear solution generally containing about 5 percent Acetic Acid 80% and 95 percent water.
Vinegar is used as a food ingredient and can also be an ingredient in personal care products, household cleaners, pet shampoos and many other products for the home:

-vinegar and baking soda
*Food Preparation:
Vinegar is a common food ingredient, often used as a brine in pickling liquids, vinaigrettes, marinades and other salad dressings.
Vinegar also can be used in food preparation to help control Salmonella contamination in meat and poultry products.

*Cleaning:
Vinegar can be used throughout the home as a window cleaner, to clean automatic coffee makers and dishes, as a rinsing agent for dishwashers, and to clean bathroom tile and grout.
Vinegar can also be used to clean food-related tools and equipment because it generally does not leave behind a harmful residue and requires less rinsing.

*Gardening:
In concentrations of 10 to 20 percent, Acetic Acid 80% can be used as a weed killer on gardens and lawns.
When used as an herbicide, the Acetic Acid 80% can kill weeds that have emerged from the soil, but does not affect the roots of the weed, so they can regrow.

When Acetic Acid 80% is at 99.5 percent concentration, it is referred to as glacial Acetic Acid 80%.
Glacial Acetic Acid 80% has a variety of uses, including as a raw material and solvent in the production of other chemical products.



INDUSTRIAL APPLICATIONS FOR ACETIC ACID 80% INCLUDE:
*Vinyl Acetate, cellulose fibers and plastics:
Acetic Acid 80% is used to make many chemicals, including vinyl acetate, acetic anhydride and acetate esters.
Vinyl acetate is used to make polyvinyl acetate, a polymer used in paints, adhesives, plastics and textile finishes.

Acetic anhydride is used in the manufacture of cellulose acetate fibers and plastics used for photographic film, clothing and coatings.
Acetic Acid 80% is also used in the chemical reaction to produce purified terephthalic acid (PTA), which is used to manufacture the PET plastic resin used in synthetic fibers, food containers, beverage bottles and plastic films.

*Solvents:
Acetic Acid 80% is a hydrophilic solvent, similar to ethanol.
Acetic Acid 80% dissolves compounds such as oils, sulfur and iodine and mixes with water, chloroform and hexane.

*Acidizing oil and gas:
Acetic Acid 80% can help reduce metal corrosion and scale build-up in oil and gas well applications.
Acetic Acid 80% is also used in oil well stimulation to improve flow and increase production of oil and gas.

*Pharmaceuticals and vitamins:
The pharmaceutical industry uses Acetic Acid 80% in the manufacture of vitamins, antibiotics, hormones and other products.

*Food Processing:
Acetic Acid 80% is commonly used as a cleaning and disinfecting product in food processing plants.

*Other uses:
Salts of Acetic Acid 80% and various rubber and photographic chemicals are made from Acetic Acid 80%.
Acetic Acid 80% and its sodium salt are commonly used as a food preservative.



WHAT CAN YOU USE ACETIC ACID 80% FOR?
*Removing stubborn limescale on sanitary facilities and kitchen appliances.
*Combating green deposits on terraces, garden furniture and stone surfaces.
*Descaling of industrial machines and equipment.
*Cleaning and disinfection in the food industry, if adequately diluted.
*Use as raw material in chemical synthesis for the production of esters, acetic esters and various organic compounds.
*In agriculture for regulating the pH value of the soil.
*As a preservative in food processing, for example when pickling vegetables.
*Cleaning and restoration of facades and monuments.



USES OF ACETIC ACID 80%:
The chemical reagent for the processing of chemical compounds is Acetic Acid 80%.
In the production of vinyl acetate monomer, acetic anhydride, and ester production, the use of Acetic Acid 80% is important.


*Vinyl Acetate Monomer:
Vinyl acetate monomer (VAM) processing is the main application of Acetic Acid 80%.
Vinyl acetate undergoes polymerization to produce polyvinyl acetate or other polymers, which are components of paints and adhesives.

The reaction consists of ethylene and Acetic Acid 80% with oxygen over a palladium catalyst.
2CH3COOH+2C2H4+O2→2CH3CO2CH=CH2+2H2O
Wood glue also utilizes vinyl acetate polymers.

*Acetic Anhydride:
Acetic anhydride is the result of the condensation of two Acetic Acid 80% molecules.
Significant use is the worldwide processing of acetic anhydride, utilizing about 25 per cent to 30 per cent of global Acetic Acid 80% production.
The key method includes Acetic Acid 80% dehydration to give ketene at 700-750 °C.

CH3CO2H→CH2=C=O+H2O
CH3CO2H+CH2=C=O→CH3CO2O

It is great for general disinfection and fighting mould and mildew since Acetic Acid 80% kills fungi and bacteria.
Acetic Acid 80% is useful in a range of traditional and green cleaning materials, such as mould and mildew cleaners, floor cleaners, sprays for cleaning and dusting, and roof cleaners, either as vinegar or as an element.

The acetyl group is in use widely in the biochemistry field.
Products made from Acetic Acid 80% are an effective metabolizer of carbohydrates and fats when bound to coenzyme A.
As a treatment for otitis externa, Acetic Acid 80% is the best and most effective drug in a health system on the World Health Organization’s List of Essential Medicines.



INDUSTRIAL APPLICATION OF ACETIC ACID 80%:
Thanks to its versatile properties, Acetic Acid 80% plays a vital role in various European industries.

*In the chemical industry, Acetic Acid 80% is a fundamental building block for producing numerous chemicals.
One example is vinyl acetate monomer (VAM), which Acetic Acid 80% is widely used to manufacture adhesives, paints, and coatings.
Acetic Acid 80% is also an essential precursor for producing acetic anhydride, esters, and cellulose acetate.

*The food and beverage industry extensively utilizes Acetic Acid 80% as a preservative and flavoring agent.
Vinegar, primarily composed of Acetic Acid 80%, finds widespread use in cooking, pickling, and salad dressings.

*In the pharmaceutical industry, Acetic Acid 80% is a crucial intermediate in synthesizing pharmaceuticals, including antibiotics, vitamins, and analgesics.
Acetic Acid 80%'s versatile nature allows for the production of a wide range of medications.

*The textile industry relies on Acetic Acid 80% to manufacture synthetic acetate fibers.
Acetate fibers are commonly used in clothing, upholstery, and textiles due to their excellent draping properties and durability.



WHAT IS ACETIC ACID 80% IN FOOD?
Acetic Acid 80% is a food additive that is commonly used as a preservative, flavor enhancer, and pH regulator.
Acetic Acid 80% is a natural acid found in vinegar and is also produced synthetically for use in food applications.
Acetic Acid 80% is generally regarded as safe for consumption at low levels, and it is commonly used in condiments, pickled foods, sauces, and dressings to provide a tangy taste and extend shelf life.
However, excessive consumption of Acetic Acid 80% can cause irritation to the digestive system.
As with any food additive, it is important to consume Acetic Acid 80% in moderation and maintain a balanced diet.



ACETIC ACID 80% IN EVERYDAY LIFE:
Acetic Acid 80% is found in many everyday products as described above, such as food, cleaning products and cosmetics, among others.
Of all of them, vinegar is one of the most important ones, as Acetic Acid 80% has different uses, such as for cooking or cleaning.
Acetic Acid 80% is an infallible product when it comes to dealing with stubborn stains such as dog urine, rust or other dirt.



PHYSICAL PROPERTIES OF ACETIC ACID 80%:
Acetic Acid 80% is a colorless liquid; with a strong vinegar-like odour.
Acetic Acid 80% is considered a volatile organic compound by the National Pollutant Inventory.
Specific Gravity: 1.049 @ 25°C
Melting Point: 16.7°C
Boiling Point: 118°C
Vapour pressure: 1.5 kPa @ 20°C



CHEMICAL PROPERTIES OF ACETIC ACID 80%:
Acetic Acid 80% is hygroscopic, meaning that it tends to absorb moisture.
Acetic Acid 80% mixes with ethyl alcohol, glycerol, ether, carbon tetrachloride and water and reacts with oxidants and bases.
Concentrated Acetic Acid 80% is corrosive and attacks many metals forming flammable or explosive gases.
Acetic Acid 80% can also attack some forms of plastic, rubber and coatings.



HEALTH BENEFITS OF ACETIC ACID 80%:
1. Kills Bacteria:
Vinegar has long been used as a natural disinfectant, largely due to its content of Acetic Acid 80%.
Acetic Acid 80% has powerful antibacterial properties and can be effective at killing off several specific strains of bacteria.

In fact, one 2014 in vitro study found that Acetic Acid 80% was able to block the growth of myobacteria, a genus of bacteria responsible for causing tuberculosis and leprosy.
Other research shows that vinegar may also protect against bacterial growth, which may be partially due to the presence of Acetic Acid 80%.


2. Reduces Blood Pressure:
Not only does high blood pressure place extra strain on the heart muscle and cause it to slowly weaken over time, but high blood pressure is also a major risk factor for heart disease.
In addition to modifying your diet and exercise routine, promising research has found that Acetic Acid 80% may also help control blood pressure.


3. Decreases Inflammation:
Acute inflammation plays an important role in immune function, helping to defend the body against illness and infection.
Sustaining high levels of inflammation long-term, however, can have a detrimental effect on health, with studies showing that inflammation could contribute to the development of chronic conditions like heart disease and cancer.
Acetic Acid 80% is thought to reduce inflammation to help protect against disease.


4. Supports Weight Loss:
Some research suggests that Acetic Acid 80% could help support weight control by aiding in weight loss.


5. Promotes Blood Sugar Control:
Apple cider vinegar has been well-studied for its ability to support blood sugar control.
Research shows that Acetic Acid 80%, one of the primary components found in apple cider vinegar, may play a role in its powerful blood sugar-lowering properties.

In one study, consuming vinegar with Acetic Acid 80% alongside a high-carb meal was found to reduce blood sugar and insulin levels thanks to its ability to slow down the emptying of the stomach.
Another in vitro study had similar findings, reporting that Acetic Acid 80% decreased the activity of several enzymes involved in carbohydrate metabolism, which could decrease the absorption of carbs and sugar in the small intestine.



NOMENCLATURE OF ACETIC ACID 80%:
The trivial name "Acetic Acid 80%" is the most commonly used and preferred IUPAC name.
The systematic name "ethanoic acid", a valid IUPAC name, is constructed according to the substitutive nomenclature.
The name "Acetic Acid 80%" derives from the Latin word for vinegar, "acetum", which is related to the word "acid" itself.

"Glacial Acetic Acid 80%" is a name for water-free (anhydrous) Acetic Acid 80%.
Similar to the German name "Eisessig" ("ice vinegar"), the name comes from the solid ice-like crystals that form with agitation, slightly below room temperature at 16.6 °C (61.9 °F).

Acetic Acid 80% can never be truly water-free in an atmosphere that contains water, so the presence of 0.1% water in glacial Acetic Acid 80% lowers its melting point by 0.2 °C.
A common symbol for Acetic Acid 80% is AcOH (or HOAc), where Ac is the pseudoelement symbol representing the acetyl group CH3−C(=O)−; the conjugate base, acetate (CH3COO−), is thus represented as AcO−.

(The symbol Ac for the acetyl functional group is not to be confused with the symbol Ac for the element actinium; context prevents confusion among organic chemists).
To better reflect its structure, Acetic Acid 80% is often written as CH3−C(O)OH, CH3−C(=O)OH, CH3COOH, and CH3CO2H.

In the context of acid–base reactions, the abbreviation HAc is sometimes used, where Ac in this case is a symbol for acetate (rather than acetyl).
Acetate is the ion resulting from loss of H+ from Acetic Acid 80%.
The name "acetate" can also refer to a salt containing this anion, or an ester of Acetic Acid 80%.



HISTORY OF ACETIC ACID 80%:
Vinegar was known early in civilization as the natural result of exposure of beer and wine to air because Acetic Acid 80%-producing bacteria are present globally.
The use of Acetic Acid 80% in alchemy extends into the third century BC, when the Greek philosopher Theophrastus described how vinegar acted on metals to produce pigments useful in art, including white lead (lead carbonate) and verdigris, a green mixture of copper salts including copper(II) acetate.

Ancient Romans boiled soured wine to produce a highly sweet syrup called sapa.
Sapa that was produced in lead pots was rich in lead acetate, a sweet substance also called sugar of lead or sugar of Saturn, which contributed to lead poisoning among the Roman aristocracy.

In the 16th-century German alchemist Andreas Libavius described the production of acetone from the dry distillation of lead acetate, ketonic decarboxylation.

The presence of water in vinegar has such a profound effect on Acetic Acid 80%'s properties that for centuries chemists believed that glacial Acetic Acid 80% and the acid found in vinegar were two different substances.
French chemist Pierre Adet proved them identical.


*Crystallised Acetic Acid 80%
In 1845 German chemist Hermann Kolbe synthesised Acetic Acid 80% from inorganic compounds for the first time.
This reaction sequence consisted of chlorination of carbon disulfide to carbon tetrachloride, followed by pyrolysis to tetrachloroethylene and aqueous chlorination to trichloroAcetic Acid 80%, and concluded with electrolytic reduction to Acetic Acid 80%.

By 1910, most glacial Acetic Acid 80% was obtained from the pyroligneous liquor, a product of the distillation of wood.
The Acetic Acid 80% was isolated by treatment with milk of lime, and the resulting calcium acetate was then acidified with sulfuric acid to recover Acetic Acid 80%.
At that time, Germany was producing 10,000 tons of glacial Acetic Acid 80%, around 30% of which was used for the manufacture of indigo dye.

Because both methanol and carbon monoxide are commodity raw materials, methanol carbonylation long appeared to be attractive precursors to Acetic Acid 80%.
Henri Dreyfus at British Celanese developed a methanol carbonylation pilot plant as early as 1925.

However, a lack of practical materials that could contain the corrosive reaction mixture at the high pressures needed (200 atm or more) discouraged commercialization of these routes.
The first commercial methanol carbonylation process, which used a cobalt catalyst, was developed by German chemical company BASF in 1963.

In 1968, a rhodium-based catalyst (cis−[Rh(CO)2I2]−) was discovered that could operate efficiently at lower pressure with almost no by-products.
US chemical company Monsanto Company built the first plant using this catalyst in 1970, and rhodium-catalyzed methanol carbonylation became the dominant method of Acetic Acid 80% production (see Monsanto process).

In the late 1990s, BP Chemicals commercialised the Cativa catalyst ([Ir(CO)2I2]−), which is promoted by iridium for greater efficiency.
Known as the Cativa process, the iridium-catalyzed production of glacial Acetic Acid 80% is greener, and has largely supplanted the Monsanto process, often in the same production plants.


*Interstellar medium
Interstellar Acetic Acid 80% was discovered in 1996 by a team led by David Mehringer using the former Berkeley-Illinois-Maryland Association array at the Hat Creek Radio Observatory and the former Millimeter Array located at the Owens Valley Radio Observatory.

It was first detected in the Sagittarius B2 North molecular cloud (also known as the Sgr B2 Large Molecule Heimat source).
Acetic Acid 80% has the distinction of being the first molecule discovered in the interstellar medium using solely radio interferometers; in all previous ISM molecular discoveries made in the millimetre and centimetre wavelength regimes, single dish radio telescopes were at least partly responsible for the detections.



PHYSICAL DETAILS AND PROPERTIES OF ACETIC ACID 80%:
Acetic Acid 80%, or ethanoic acid, is a clear, colorless liquid with a pungent vinegar-like odor.
Acetic Acid 80% has a molecular formula CH₃COOH and a molecular weight of 60.05 g/mol.
With a boiling point of 118.1, °C and a melting point of 16.6°C, Acetic Acid 80% is highly soluble in water and miscible with most organic solvents.
These physical properties make Acetic Acid 80% a versatile compound for various industrial applications.



PRODUCTION METHODS OF ACETIC ACID 80%:
Acetic Acid 80% is primarily produced through two main methods: methanol carbonylation and oxidation of acetaldehyde.
The first method, methanol carbonylation, is the most common process for large-scale Acetic Acid 80% production.
Acetic Acid 80% involves the reaction of methanol with carbon monoxide in the presence of a catalyst, typically rhodium or iodine compounds.

This catalytic reaction yields Acetic Acid 80% as the primary product.
The second method involves the oxidation of acetaldehyde. Acetaldehyde can be oxidized using various catalysts, including palladium or copper, producing Acetic Acid 80% as a byproduct.



WHAT IS THE PURPOSE OF ACETIC ACID 80% IN ADDITIVES FOODS?
Acetic Acid 80% is commonly used as a food additive.
Acetic Acid 80% serves multiple purposes in additives foods.
Firstly, Acetic Acid 80% acts as a preservative by inhibiting the growth of bacteria and fungi, thus extending the shelf life of the product.
Secondly, Acetic Acid 80% enhances the flavor and aroma of the food by giving it a tangy and sour taste.
Additionally, Acetic Acid 80% can also be used as an acidity regulator and pH control agent in certain food products.



FUNCTIONS OF ACETIC ACID 80%:
1. Acidity Regulator / Buffering Agent - Changes or maintains the acidity or basicity of food/cosmetics.
2. Drug / Medicine - Treats, alleviates, cures, or prevents sickness. As officially declared by a governmental drug/medicine regulatory body
3. Exfoliant - Removes dead cells at the surface of the skin
4. Experimental / Patented - Relatively new ingredient with limited data available
5. Insecticide / Pesticide - Kills or inhibits unwanted organisms
6. Preservative - Prevents and inhibits the growth of unwanted microorganisms which may be harmful
7. Solvent (Cosmetics) - Enhances the properties of other ingredients



IS ACETIC ACID 80% SAFE?
Acetic Acid 80% is also known as Acetic Acid 80%, which is a widely used food additive.
Acetic Acid 80% is considered safe for consumption by regulatory authorities such as the Food and Drug Administration (FDA) and the European Food Safety Authority (EFSA).



HEALTH BENEFITS OF ACETIC ACID 80%:
Acetic Acid 80% has powerful antibacterial properties.
Acetic Acid 80% helps to reduce blood pressure.
Acetic Acid 80% also help to reduce inflammation.
Acetic Acid 80% promotes blood sugar control.
Acetic Acid 80% also supports weight loss.



FUNCTION & CHARACTERISTICS OF ACETIC ACID 80%:
Acetic Acid 80% is used as a preservative against bacteria and fungi.
In mayonnaise Acetic Acid 80% is added to increase the inactivation of Salmonella .
The highest activity of Acetic Acid 80% is at low pH.
Acetic Acid 80% can also be used as a buffer in acidic foods.
Acetic Acid 80% is also used as an aroma component.



ORIGIN OF ACETIC ACID 80%:
Natural acid, present in most fruits.
Acetic Acid 80% is produced by bacterial fermentation and thus present in all fermented products.
Commercially produced by bacterial fermentation of sugar, molasses or alcohol or by chemical synthesis from acetealdehyde.



IS ACETIC ACID 80% GLUTEN FREE?
Yes.
Acetic Acid 80% is gluten free and widely used in gluten free food to provide sour taste to sour drinks.



WHY IS ACETIC ACID 80% GLUTEN FREE?
Gluten is a type of elastic grain protein that helps wheat, rye and barley hold their shape.
Because of its glue-like properties, gluten is often added to other food products—pasta, sauces, crackers, baked goods—to thicken or bind those products together.
Raw materials used in manufacturing of Acetic Acid 80% are Acetyl ketene; So the manufacturing process of it is gluten free.
So, Acetic Acid 80% is gluten free.



IS ACETIC ACID 80% SAFE FOR CONSUMPTION IN ADDITIVES FOODS?
Acetic Acid 80% is considered safe for consumption in additives foods.
Acetic Acid 80% is a naturally occurring substance and is commonly found in vinegar.
Acetic Acid 80% is used as a flavoring agent and food preservative in various processed foods.
However, Acetic Acid 80% is important to note that excessive consumption of Acetic Acid 80% may have adverse effects on health.
Acetic Acid 80% is always recommended to consume additives foods in moderation and as part of a balanced diet.



HOW DOES ACETIC ACID 80% CONTRIBUTE TO THE PRESERVATION OF ADDITIVES FOODS?
Acetic Acid 80% contributes to the preservation of additives foods in several ways.
Firstly, Acetic Acid 80% has antimicrobial properties that inhibit the growth of bacteria, yeasts, and molds, reducing the risk of food spoilage and extending the shelf life of products.

Additionally, Acetic Acid 80% acts as a pH regulator in additives foods.
Acetic Acid 80% helps maintain acidity levels, creating an environment that is unfavorable for the growth of certain microorganisms.
This is particularly important in canned and pickled foods where acidity plays a crucial role in preventing the growth of harmful bacteria like Clostridium botulinum.

Moreover, Acetic Acid 80% also contributes to the preservation of additives foods by enhancing flavor.
Acetic Acid 80% adds a characteristic tartness or sourness, which can improve the taste profile of various products.
By enhancing the overall sensory experience, Acetic Acid 80% can help prolong the consumer acceptability and consumption of additives foods.

In summary, Acetic Acid 80% plays a vital role in preserving additives foods by acting as an antimicrobial agent, pH regulator, and flavor enhancer.
Acetic Acid 80%'s usage ensures the safety and prolonged shelf life of various food products.
In conclusion, Acetic Acid 80% plays a crucial role as an additive in the food industry.

With its versatile properties, Acetic Acid 80% enhances flavors and acts as a natural preservative, increasing the shelf life of various food products.
Despite some concerns about its safety and potential health effects, research suggests that when consumed in moderation, Acetic Acid 80% is generally considered safe for consumption.

As consumers, it is important to stay informed about the presence of Acetic Acid 80% in our food products and make informed choices.
So, next time you come across the ingredient label with Acetic Acid 80%, rest assured that it can be embraced as a safe and effective addition to additive foods.



PROPERTIES OF ACETIC ACID 80%:
-Acetic Acid 80% crystals:

*Acidity
The hydrogen centre in the carboxyl group (−COOH) in carboxylic acids such as Acetic Acid 80% can separate from the molecule by ionization:
CH3COOH ⇌ CH3CO−2 + H+

Because of this release of the proton (H+), Acetic Acid 80% has acidic character.
Acetic Acid 80% is a weak monoprotic acid.
In aqueous solution, Acetic Acid 80% has a pKa value of 4.76.

Acetic Acid 80%'s conjugate base is acetate (CH3COO−).
A 1.0 M solution (about the concentration of domestic vinegar) has a pH of 2.4, indicating that merely 0.4% of the Acetic Acid 80% molecules are dissociated.
Only in very dilute (< 10−6 M) solution, Acetic Acid 80% is >90% dissociated.

*Deprotonation equilibrium of Acetic Acid 80% in water
Cyclic dimer of Acetic Acid 80%; dashed green lines represent hydrogen bonds



STRUCTURE OF ACETIC ACID 80%:
In solid Acetic Acid 80%, the molecules form chains of individual molecules interconnected by hydrogen bonds.
In the vapour phase at 120 °C (248 °F), dimers can be detected.

Dimers also occur in the liquid phase in dilute solutions with non-hydrogen-bonding solvents, and to a certain extent in pure Acetic Acid 80%, but are disrupted by hydrogen-bonding solvents.

The dissociation enthalpy of the dimer is estimated at 65.0–66.0 kJ/mol, and the dissociation entropy at 154–157 J mol−1 K−1.
Other carboxylic acids engage in similar intermolecular hydrogen bonding interactions.



SOLVENT PROPERTIES OF ACETIC ACID 80%:
Liquid Acetic Acid 80% is a hydrophilic (polar) protic solvent, similar to ethanol and water.
With a relative static permittivity (dielectric constant) of 6.2, Acetic Acid 80% dissolves not only polar compounds such as inorganic salts and sugars, but also non-polar compounds such as oils as well as polar solutes.

Acetic Acid 80% is miscible with polar and non-polar solvents such as water, chloroform, and hexane.
With higher alkanes (starting with octane), Acetic Acid 80% is not miscible at all compositions, and solubility of Acetic Acid 80% in alkanes declines with longer n-alkanes.

The solvent and miscibility properties of Acetic Acid 80% make it a useful industrial chemical, for example, as a solvent in the production of dimethyl terephthalate.



BIOCHEMISTRY OF ACETIC ACID 80%:
At physiological pHs, Acetic Acid 80% is usually fully ionised to acetate.
The acetyl group, formally derived from Acetic Acid 80%, is fundamental to all forms of life.
Typically, Acetic Acid 80% is bound to coenzyme A by acetyl-CoA synthetase enzymes, where it is central to the metabolism of carbohydrates and fats.

Unlike longer-chain carboxylic acids (the fatty acids), Acetic Acid 80% does not occur in natural triglycerides.
Most of the aceate generated in cells for use in acetyl-CoA is synthesized directly from ethanol or pyruvate.
However, the artificial triglyceride triacetin (glycerine triacetate) is a common food additive and is found in cosmetics and topical medicines; this additive is metabolized to glycerol and Acetic Acid 80% in the body.

Acetic Acid 80% is produced and excreted by Acetic Acid 80% bacteria, notably the genus Acetobacter and Clostridium acetobutylicum.
These bacteria are found universally in foodstuffs, water, and soil, and Acetic Acid 80% is produced naturally as fruits and other foods spoil.
Acetic Acid 80% is also a component of the vaginal lubrication of humans and other primates, where it appears to serve as a mild antibacterial agent.



PRODUCTION OF ACETIC ACID 80%:
Acetic Acid 80% is produced industrially both synthetically and by bacterial fermentation.
About 75% of Acetic Acid 80% made for use in the chemical industry is made by the carbonylation of methanol, explained below.

The biological route accounts for only about 10% of world production, but Acetic Acid 80% remains important for the production of vinegar because many food purity laws require vinegar used in foods to be of biological origin.
Other processes are methyl formate isomerization, conversion of syngas to Acetic Acid 80%, and gas phase oxidation of ethylene and ethanol.

Acetic Acid 80% can be purified via fractional freezing using an ice bath.
The water and other impurities will remain liquid while the Acetic Acid 80% will precipitate out.
As of 2003–2005, total worldwide production of virgin Acetic Acid 80% was estimated at 5 Mt/a (million tonnes per year), approximately half of which was produced in the United States.

European production was approximately 1 Mt/a and declining, while Japanese production was 0.7 Mt/a.
Another 1.5 Mt were recycled each year, bringing the total world market to 6.5 Mt/a.
Since then, the global production has increased from 10.7 Mt/a in 2010 to 17.88 Mt/a in 2023.


*Methanol carbonylation:
Most Acetic Acid 80% is produced by methanol carbonylation.
In this process, methanol and carbon monoxide react to produce Acetic Acid 80% according to the equation:
The process involves iodomethane as an intermediate, and occurs in three steps.
A metal carbonyl catalyst is needed for the carbonylation (step 2).

CH3OH + HI → CH3I + H2O
CH3I + CO → CH3COI
CH3COI + H2O → CH3COOH + HI

Two related processes exist for the carbonylation of methanol: the rhodium-catalyzed Monsanto process, and the iridium-catalyzed Cativa process.
The latter process is greener and more efficient and has largely supplanted the former process.

Catalytic amounts of water are used in both processes, but the Cativa process requires less, so the water-gas shift reaction is suppressed, and fewer by-products are formed.
By altering the process conditions, acetic anhydride may also be produced in plants using rhodium catalysis.


*Acetaldehyde oxidation:
Prior to the commercialization of the Monsanto process, most Acetic Acid 80% was produced by oxidation of acetaldehyde.
This remains the second-most-important manufacturing method, although Acetic Acid 80% is usually not competitive with the carbonylation of methanol.

The acetaldehyde can be produced by hydration of acetylene.
This was the dominant technology in the early 1900s.

Light naphtha components are readily oxidized by oxygen or even air to give peroxides, which decompose to produce Acetic Acid 80% according to the chemical equation, illustrated with butane:

2 C4H10 + 5 O2 → 4 CH3CO2H + 2 H2O
Such oxidations require metal catalyst, such as the naphthenate salts of manganese, cobalt, and chromium.

The typical reaction is conducted at temperatures and pressures designed to be as hot as possible while still keeping the butane a liquid.
Typical reaction conditions are 150 °C (302 °F) and 55 atm.
Side-products may also form, including butanone, ethyl acetate, formic acid, and propionic acid.

These side-products are also commercially valuable, and the reaction conditions may be altered to produce more of them where needed.
However, the separation of Acetic Acid 80% from these by-products adds to the cost of the process.
Similar conditions and catalysts are used for butane oxidation, the oxygen in air to produce Acetic Acid 80% can oxidize acetaldehyde.

2 CH3CHO + O2 → 2 CH3CO2H
Using modern catalysts, this reaction can have an Acetic Acid 80% yield greater than 95%.
The major side-products are ethyl acetate, formic acid, and formaldehyde, all of which have lower boiling points than Acetic Acid 80% and are readily separated by distillation.


*Ethylene oxidation
Acetaldehyde may be prepared from ethylene via the Wacker process, and then oxidised as above.
In more recent times, chemical company Showa Denko, which opened an ethylene oxidation plant in Ōita, Japan, in 1997, commercialised a cheaper single-stage conversion of ethylene to Acetic Acid 80%.

The process is catalyzed by a palladium metal catalyst supported on a heteropoly acid such as silicotungstic acid.
A similar process uses the same metal catalyst on silicotungstic acid and silica:

C2H4 + O2 → CH3CO2H
It is thought to be competitive with methanol carbonylation for smaller plants (100–250 kt/a), depending on the local price of ethylene.


*Oxidative fermentation:
For most of human history, Acetic Acid 80% bacteria of the genus Acetobacter have made Acetic Acid 80%, in the form of vinegar.
Given sufficient oxygen, these bacteria can produce vinegar from a variety of alcoholic foodstuffs.

Commonly used feeds include apple cider, wine, and fermented grain, malt, rice, or potato mashes.
The overall chemical reaction facilitated by these bacteria is:

C2H5OH + O2 → CH3COOH + H2O
A dilute alcohol solution inoculated with Acetobacter and kept in a warm, airy place will become vinegar over the course of a few months.
Industrial vinegar-making methods accelerate this process by improving the supply of oxygen to the bacteria.

The first batches of vinegar produced by fermentation probably followed errors in the winemaking process.
If must is fermented at too high a temperature, acetobacter will overwhelm the yeast naturally occurring on the grapes.

As the demand for vinegar for culinary, medical, and sanitary purposes increased, vintners quickly learned to use other organic materials to produce vinegar in the hot summer months before the grapes were ripe and ready for processing into wine.
This method was slow, however, and not always successful, as the vintners did not understand the process.

One of the first modern commercial processes was the "fast method" or "German method", first practised in Germany in 1823.
In this process, fermentation takes place in a tower packed with wood shavings or charcoal.

The alcohol-containing feed is trickled into the top of the tower, and fresh air supplied from the bottom by either natural or forced convection.
The improved air supply in this process cut the time to prepare vinegar from months to weeks.

Nowadays, most vinegar is made in submerged tank culture, first described in 1949 by Otto Hromatka and Heinrich Ebner.
In this method, alcohol is fermented to vinegar in a continuously stirred tank, and oxygen is supplied by bubbling air through the solution.
Using modern applications of this method, vinegar of 15% Acetic Acid 80% can be prepared in only 24 hours in batch process, even 20% in 60-hour fed-batch process.


*Anaerobic fermentation:
Species of anaerobic bacteria, including members of the genus Clostridium or Acetobacterium, can convert sugars to Acetic Acid 80% directly without creating ethanol as an intermediate.
The overall chemical reaction conducted by these bacteria may be represented as:

C6H12O6 → 3 CH3COOH
These acetogenic bacteria produce Acetic Acid 80% from one-carbon compounds, including methanol, carbon monoxide, or a mixture of carbon dioxide and hydrogen:

2 CO2 + 4 H2 → CH3COOH + 2 H2O
This ability of Clostridium to metabolize sugars directly, or to produce Acetic Acid 80% from less costly inputs, suggests that these bacteria could produce Acetic Acid 80% more efficiently than ethanol-oxidizers like Acetobacter.

However, Clostridium bacteria are less acid-tolerant than Acetobacter.
Even the most acid-tolerant Clostridium strains can produce vinegar in concentrations of only a few per cent, compared to Acetobacter strains that can produce vinegar in concentrations up to 20%.

At present, it remains more cost-effective to produce vinegar using Acetobacter, rather than using Clostridium and concentrating it.
As a result, although acetogenic bacteria have been known since 1940, their industrial use is confined to a few niche applications.



REACTIONS OF ACETIC ACID 80%:
Acetic Acid 80% undergoes the typical chemical reactions of a carboxylic acid.
Upon treatment with a standard base, Acetic Acid 80% converts to metal acetate and water.
With strong bases (e.g., organolithium reagents), Acetic Acid 80% can be doubly deprotonated to give LiCH2COOLi.

Reduction of Acetic Acid 80% gives ethanol.
The OH group is the main site of reaction, as illustrated by the conversion of Acetic Acid 80% to acetyl chloride.
Other substitution derivatives include acetic anhydride; this anhydride is produced by loss of water from two molecules of Acetic Acid 80%.

Esters of Acetic Acid 80% can likewise be formed via Fischer esterification, and amides can be formed.
When heated above 440 °C (824 °F), Acetic Acid 80% decomposes to produce carbon dioxide and methane, or to produce ketene and water:
CH3COOH → CH4 + CO2
CH3COOH → CH2=C=O + H2O



REACTIONS WITH INORGANIC COMPOUNDS OF ACETIC ACID 80%:
Acetic Acid 80% is mildly corrosive to metals including iron, magnesium, and zinc, forming hydrogen gas and salts called acetates:
Mg + 2 CH3COOH → (CH3COO)2Mg + H2

Because aluminium forms a passivating acid-resistant film of aluminium oxide, aluminium tanks are used to transport Acetic Acid 80%.
Containers lined with glass, stainless steel or polyethylene are also used for this purpose.
Metal acetates can also be prepared from Acetic Acid 80% and an appropriate base, as in the popular "baking soda + vinegar" reaction giving off sodium acetate:

NaHCO3 + CH3COOH → CH3COONa + CO2 + H2O
A colour reaction for salts of Acetic Acid 80% is iron(III) chloride solution, which results in a deeply red colour that disappears after acidification.
A more sensitive test uses lanthanum nitrate with iodine and ammonia to give a blue solution.
Acetates when heated with arsenic trioxide form cacodyl oxide, which can be detected by its malodorous vapours.



OTHER DERIVATIVES OF ACETIC ACID 80%:
Organic or inorganic salts are produced from Acetic Acid 80%.
Some commercially significant derivatives:
Sodium acetate, used in the textile industry and as a food preservative (E262).

Copper(II) acetate, used as a pigment and a fungicide.
Aluminium acetate and iron(II) acetate—used as mordants for dyes.
Palladium(II) acetate, used as a catalyst for organic coupling reactions such as the Heck reaction.

Halogenated Acetic Acid 80%s are produced from Acetic Acid 80%.
Some commercially significant derivatives:
ChloroAcetic Acid 80% (monochloroAcetic Acid 80%, MCA), dichloroAcetic Acid 80% (considered a by-product), and trichloroAcetic Acid 80%.

MCA is used in the manufacture of indigo dye.
BromoAcetic Acid 80%, which is esterified to produce the reagent ethyl bromoacetate.
TrifluoroAcetic Acid 80%, which is a common reagent in organic synthesis.
Amounts of Acetic Acid 80% used in these other applications together account for another 5–10% of Acetic Acid 80% use worldwide



STRUCTURE OF ACETIC ACID 80%:
It can be observed in the solid-state of Acetic Acid 80% that there is a chain of molecules wherein individual molecules are connected to each other via hydrogen bonds.
Dimers of ethanoic acid in Acetic Acid 80%'s vapour phase can be found at temperatures approximating to 120o

Even in the liquid phase of ethanoic acid, Acetic Acid 80%'s dimers can be found when it is present in a dilute solution.
These dimers are adversely affected by solvents that promote hydrogen bonding.

The structure of Acetic Acid 80% is given by CH3(C=O)OH, or CH3CO2H
Structurally, Acetic Acid 80% is the second simplest carboxylic acid (the simplest being formic acid, HCOOH), and is essentially a methyl group with a carboxyl functional group attached to it.



PREPARATION OF ACETIC ACID 80%:
Acetic Acid 80% is produced industrially via the carbonylation of methanol.
The chemical equations for the three steps involved in this process are provided below.
CH3OH (methanol) + HI (hydrogen iodide) → CH3I (methyl iodide intermediate) + H2O

CH3I + CO (carbon monoxide) → CH3COI (acetyl iodide)
CH3COI + H2O → CH3COOH (Acetic Acid 80%) + HI

Here, a methyl iodide intermediate is generated from the reaction between methanol and hydrogen iodide.
This intermediate is then reacted with carbon monoxide and the resulting compound is treated with water to afford the Acetic Acid 80% product.
It is important to note that a metal carbonyl complex must be used as a catalyst for step 2 of this process.



OTHER METHODS OF PREPARING ACETIC ACID 80%:
Some naphthalene salts of cobalt, chromium, and manganese can be employed as metal catalysts in the oxidation of acetaldehyde.
The chemical equation for this reaction can be written as:
O2 + 2CH3CHO → 2CH3COOH

Ethylene (C2H4) can be oxidized into Acetic Acid 80% with the help of a palladium catalyst and a heteropoly acid, as described by the following chemical reaction.
O2 + C2H4 → CH3COOH

Some anaerobic bacteria have the ability to directly convert sugar into Acetic Acid 80%.
C6H12O6 → 3CH3COOH
It can be noted that no ethanol intermediates are formed in the anaerobic fermentation of sugar by these bacteria.



PHYSICAL PROEPRTIES OF ACETIC ACID 80%:
Even though ethanoic acid is considered to be a weak acid, in its concentrated form, it possesses strong corrosive powers and can even attack the human skin if exposed to it.
Some general properties of Acetic Acid 80% are listed below.

Ethanoic acid appears to be a colourless liquid and has a pungent smell.
At STP, the melting and boiling points of ethanoic acid are 289K and 391K respectively.
The molar mass of Acetic Acid 80% is 60.052 g/mol and its density in the liquid form is 1.049 g.cm-3.

The carboxyl functional group in ethanoic acid can cause ionization of the compound, given by the reaction: CH3COOH ⇌ CH3COO– + H+
The release of the proton, described by the equilibrium reaction above, is the root cause of the acidic quality of Acetic Acid 80%.
The acid dissociation constant (pKa) of ethanoic acid in a solution of water is 4.76.

The conjugate base of Acetic Acid 80% is acetate, given by CH3COO–.
The pH of an ethanoic acid solution of 1.0M concentration is 2.4, which implies that it does not dissociate completely.
In its liquid form, Acetic Acid 80% is a polar, protic solvent, with a dielectric constant of 6.2.

The metabolism of carbohydrates and fats in many animals is centered around the binding of Acetic Acid 80% to coenzyme A.
Generally, this compound is produced via the reaction between methanol and carbon monoxide (carbonylation of methanol).



CHEMICAL PROPERTIES OF ACETIC ACID 80%:
The chemical reactions undergone by Acetic Acid 80% are similar to those of other carboxylic acids.
When heated to temperatures above 440oC, this compound undergoes decomposition to yield either methane and carbon dioxide or water and ethenone, as described by the following chemical equations.

CH3COOH + Heat → CO2 + CH4
CH3COOH + Heat → H2C=C=O + H2O
Some metals such as magnesium, zinc, and iron undergo corrosion when exposed to Acetic Acid 80%.
These reactions result in the formation of acetate salts.

2CH3COOH + Mg → Mg(CH3COO)2 (magnesium acetate) + H2
The reaction between ethanoic acid and magnesium results in the formation of magnesium acetate and hydrogen gas, as described by the chemical equation provided above.



OTHER REACTIONS OF ACETIC ACID 80%:
Acetic Acid 80% reacts with alkalis and forms acetate salts, as described below.
CH3COOH + KOH → CH3COOK + H2O
This compound also forms acetate salts by reacting with carbonates (along with carbon dioxide and water).
Examples of such reactions include:

2CH3COOH + Na2CO3 (sodium carbonate) → 2CH3COONa + CO2 + H2O
CH3COOH + NaHCO3 (sodium bicarbonate) → CH3COONa + CO2 + H2O
The reaction between PCl5 and ethanoic acid results in the formation of ethanoyl chloride.



WHAT ARE NATURAL SOURCES OF ACETIC ACID 80%?
Acetates (salts of Acetic Acid 80%) are common constituents of animal and plant tissues and are formed during the metabolism of food substances.
Acetate is readily metabolized by most tissues and may give rise to the production of ketones as intermediates.
Acetate is used by the body as a building block to make phospholipids, neutral lipids, steroids, sterols, and saturated and unsaturated fatty acids in a variety of human and animal tissue preparations.



KEY POINTS/OVERVIEW OF ACETIC ACID 80%:
One of the most common ways consumers may come into contact with Acetic Acid 80% is in the form of household vinegar, which generally contains about 5 percent Acetic Acid 80% and 95 percent water.

When Acetic Acid 80% is at 99.5 percent concentration, it is referred to a glacial Acetic Acid 80%, which can be used as raw material and solvent in the production of other chemical products.

Industrial applications of glacial Acetic Acid 80% include producing vinyl acetate, as solvent to dissolve oils, sulfur and iodine; acidizing oil and gas; manufacturing pharmaceuticals and vitamins, and food processing.



HOW ACETIC ACID 80% GETS INTO THE ENVIRONMENT:
Acetic Acid 80% can enter the environment from discharge and emissions from industries.
The burning of plastics or rubber, and exhaust fumes from vehicles may also release Acetic Acid 80% into the environment.
When released into soil Acetic Acid 80% evaporates into the air where it is broken down naturally by sunlight.
Levels of Acetic Acid 80% in the environment would be expected to be low.



PROPERTIES OF ACETIC ACID 80%:
Acetic Acid 80% is a smooth, colourless liquid with a 1 ppm visible, poisonous and destructive, unpleasant vinegar odour.
The melting point of Acetic Acid 80% is 16.73 ° C and the usual 117.9 ° C boiling point.
At 20°C, the density of pure Acetic Acid 80% is 1.0491.

It is highly hygroscopic Acetic Acid 80%.
It is possible to link the purity of the water solutions to their freezing point.
In carboxylic acids such as Acetic Acid 80%, the hydrogen centre in the carboxyl group −COOH can differentiate from the molecule by ionization:

Due to this proton H+1 release, Acetic Acid 80% has an acidic character.
Acetic Acid 80% is a weak monoprotic acid.
Acetic Acid 80% has a pK value of 4.76 in an aqueous solution.

Acetate CH3COO−1 is the conjugate base.
For polar and non-polar solvents such as acid, chloroform, and hexane, Acetic Acid 80% is miscible.
The molecules form chains in solid Acetic Acid 80%, with hydrogen bonds interconnecting individual molecules.

Dimers can be found in the vapour at 120 °C.
In the liquid form, dimers often exist in dilute solutions in non-hydrogen-bonding solvents and, to a certain degree, in pure Acetic Acid 80%; but are interacted with by solvents that bind to hydrogen.

Acetic Acid 80% is normally completely ionized to acetate at physiological phis.
Acetic Acid 80% is central to the metabolism of carbohydrates and fats when bound to coenzyme A.
Acetic Acid 80% does not exist in natural triglycerides, unlike longer-chain carboxylic acids (fatty acids).



DEHYDRATION OF ACETIC ACID 80%:
Dehydration of Acetic Acid 80% is one of the most important industrial uses of AD in the manufacture of aromatic acids such as terephthalic acid (TA), which involves a high purity of Acetic Acid 80%.

Two major parts are used in the manufacturing process: oxidation (where p-xylene is catalytically oxidized to produce crude TA) and PTA purification.
Acetic Acid 80%, present as a solvent in the oxidation reactor but also helpful to the reaction itself, must be isolated from the oxidation-produced water.

For the effective and economical operation of a TA facility, the recovery and storage of the Acetic Acid 80% solvent are important.
At high water temperatures, water, and Acetic Acid 80% show a pinch point, make recovering the pure acid very difficult.
Two absorbers (low and high pressure) and an acid dehydration column consist of a traditional Acetic Acid 80% recovery unit in a PTA phase.

Tall columns of 70–80 trays require the separation of Acetic Acid 80% and water by traditional distillation.
N-butyl acetate, which exhibits minimal miscibility with water and forms a heterogeneous azeotrope (b.p. 90.23°C), which is a typical azeotropic agent.
With all the water being fed to the dehydration column, n-Butyl acetate is added in appropriate amounts to form an azeotrope.

On condensation, the heterogeneous azeotrope forms two phases; an organic layer containing almost pure n-butyl acetate and an aqueous layer phase containing almost pure water.
The organic phase is recycled back to the column of dehydration, while the aqueous phase is fed to a column of stripping.
The amount of Acetic Acid 80% lost in the aqueous discharge is cut by approximately 40 per cent as AD results in a cleaner separation.



PHYSICAL and CHEMICAL PROPERTIES of ACETIC ACID 80%:
CAS: 64-19-7
Molecular Formula: C2H4O2
Molecular Weight (g/mol): 60.05
MDL Number: MFCD00036152
InChI Key: QTBSBXVTEAMEQO-UHFFFAOYSA-N
PubChem CID: 176
ChEBI: CHEBI:15366
IUPAC Name: acetic acid
SMILES: CC(O)=O
Linear Formula: CH3CO2H
Solubility Information: Solubility in water: completely soluble
Formula Weight: 60.05
Percent Purity: 80% (vol.)
Quantity: 5 L
Flash Point: >60°C
Chemical Name or Material: Acetic acid

Molecular Weight: 60.05 g/mol
XLogP3-AA: -0.2
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 2
Rotatable Bond Count: 0
Exact Mass: 60.021129366 g/mol
Monoisotopic Mass: 60.021129366 g/mol
Topological Polar Surface Area: 37.3 Ų
Heavy Atom Count: 4
Formal Charge: 0
Complexity: 31
Isotope Atom Count: 0
Defined Atom Stereocenter Count: 0
Undefined Atom Stereocenter Count: 0
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1

Compound Is Canonicalized: Yes
Chemical formula: CH3COOH
Molar mass: 60.052 g•mol−1
Appearance: Colourless liquid
Odor: Heavily vinegar-like
Density: 1.049 g/cm3 (liquid); 1.27 g/cm3 (solid)
Melting point: 16 to 17 °C; 61 to 62 °F; 289 to 290 K
Boiling point: 118 to 119 °C; 244 to 246 °F; 391 to 392 K
Solubility in water: Miscible
log P: -0.28
Vapor pressure: 1.54653947 kPa (20 °C); 11.6 mmHg (20 °C)
Acidity (pKa): 4.756
Conjugate base: Acetate
Magnetic susceptibility (χ): -31.54•10−6 cm3/mol
Refractive index (nD): 1.371 (VD = 18.19)
Viscosity: 1.22 mPa s; 1.22 cP
Dipole moment: 1.74 D

Thermochemistry
Heat capacity (C): 123.1 J K−1 mol−1
Std molar entropy (S⦵298): 158.0 J K−1 mol−1
Std enthalpy of formation (ΔfH⦵298): -483.88–483.16 kJ/mol
Std enthalpy of combustion (ΔcH⦵298): -875.50–874.82 kJ/mol
Physical state: Liquid
Color: Colorless
Odor: Stinging
Melting point/freezing point: Melting point/range: 16.2 °C - lit.
Initial boiling point and boiling range: 117 - 118 °C - lit.
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits:
Upper explosion limit: 19.9% (V),
Lower explosion limit: 4% (V)
Flash point: 39 °C - closed cup
Autoignition temperature: 463 °C
Decomposition temperature: Distillable in an undecomposed state at normal pressure.
pH: 2.5 at 50 g/L at 20 °C

Viscosity:
Kinematic viscosity: 1.17 mm2/s at 20 °C
Dynamic viscosity: 1.05 mPa•s at 25 °C
Water solubility: 602.9 g/L at 25 °C at 1.013 hPa - completely soluble
Partition coefficient (n-octanol/water): log Pow: -0.17 at 25 °C
Bioaccumulation is not expected.
Vapor pressure: 20.79 hPa at 25 °C
Density: 1.049 g/cm3 at 25 °C - lit.
Relative vapor density: 2.07
Surface tension: 28.8 mN/m at 10.0 °C
CAS number: 64-19-7
Molecular formula: C2H4O2
Molecular weight: 60.052 g/mol
Density: 1.1 ± 0.1 g/cm3
Boiling point: 117.1 ± 3.0 °C at 760 mmHg
Melting point: 16.2 °C (lit.)
Flash point: 40.0 ± 0.0 °C

EC index number: 607-002-00-6
EC number: 200-580-7
Hill Formula: C₂H₄O₂
Chemical formula: CH₃COOH
Molar Mass: 60.05 g/mol
HS Code: 2915 21 00
Boiling point: 116 - 118 °C (1013 hPa)
Density: 1.04 g/cm3 (25 °C)
Explosion limit: 4 - 19.9% (V)
Flash point: 39 °C
Ignition temperature: 485 °C
Melting Point: 16.64 °C
pH value: 2.5 (50 g/L, H₂O, 20 °C)
Vapor pressure: 20.79 hPa (25 °C)
Viscosity kinematic: 1.17 mm2/s (20 °C)

Solubility: 602.9 g/L soluble
Boiling point: 244°F
Molecular weight: 60.1
Freezing point/melting point: 62°F
Vapor pressure: 11 mmHg
Flash point: 103°F
Specific gravity: 1.05
Ionization potential: 10.66 eV
Lower explosive limit (LEL): 4.0%
Upper explosive limit (UEL): 19.9% at 200°F
NFPA health rating: 3
NFPA fire rating: 2
NFPA reactivity rating: 0
Alternative CAS RN: -
MDL Number: MFCD00036152
Storage Temperature: +20°C



FIRST AID MEASURES of ACETIC ACID 80%:
-Description of first-aid measures:
*General advice:
First aiders need to protect themselves.
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
Call in physician.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
Call a physician immediately.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Make victim drink water.
Do not attempt to neutralise.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of ACETIC ACID 80%:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up with liquid-absorbent and neutralising material.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of ACETIC ACID 80%:
-Extinguishing media:
*Suitable extinguishing media:
Water
Foam
Carbon dioxide (CO2)
Dry powder
*Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Remove container from danger zone and cool with water.
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of ACETIC ACID 80%:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles
*Skin protection:
Full contact:
Material: butyl-rubber
Minimum layer thickness: 0,7 mm
Break through time: 480 min
Splash contact:
Material: Latex gloves
Minimum layer thickness: 0,6 mm
Break through time: 30 min
*Body Protection:
Flame retardant antistatic protective clothing.
*Respiratory protection:
Recommended Filter type: filter E-(P2)
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of ACETIC ACID 80%:
-Precautions for safe handling:
*Advice on protection against fire and explosion:
Take precautionary measures against static discharge.
*Hygiene measures:
Wash hands and face after working with substance.
-Conditions for safe storage, including any incompatibilities
*Storage conditions:
Keep container tightly closed in a dry and well-ventilated place.
Moisture sensitive.



STABILITY and REACTIVITY of ACETIC ACID 80%:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature).
-Incompatible materials:
No data available

Ethylic acid; Methanecarboxylic acid; vinegar; Vinegar acid; Acetic acid, glacial; Essigsäure; ácido acético; Acide acétique; Ethanoic acid; Acetasol; Octowy kwas; Kyselina octova; Essigsaeure; Octowy kwas; Vosol; cas no:77671-22-8

Acetic oxide; Acetyl oxide; Ethanoic Anhydride; Acetic acid anhydride; Acetyl ether; Hydroxybiacetyl; Ethanoic Anhydrate; Acetanhydride; Anhydride Acetique; Anhydrid kyseliny octove; Anidride acetica; Azijnzuuranhydride; Essigsaeureanhydrid; Octowy bezwodnik; Acetyl acetate cas no: 108-24-7

1-[3-(TRIMETHOXYSILYL)PROPYL]UREA; (3-UREIDOPROPYL)TRIMETHOXYSILANE; TRIMETHOXYSILYL PROPYL UREA; UREIDOPROPYLTRIMETHOXYSILANE; .gamma.-Ureidopropyltrimethoxysilane; [3-(trimethoxysilyl)propyl]urea; Urea, 3-(trimethoxysilyl)propyl-; 3-Ureidopropyltrimethoxysilane, 50% in methanol; 1-(3-(TRIMETHOXYSILYL)PROPYL)UREA 97%; N-(Trimethoxysilylpropyl)urea; N-[3-(Trimethoxysilyl)propyl]urea; Trimethoxy[3-[(aminocarbonyl)amino]propyl]silane CAS NO:23843-64-3

SYNONYMS Ethanoyl chloride; Acetic acid chloride; CAS NO. 75-36-5

Methyl Cyanide; Cyanomethane; Ethanenitrile; methanecarbonitrile; Ethyl nitrile; AN; ethanonitrile; Acetonitril; Cyanure de methyl; Methylkyanid; cas no: 75-05-8

3-[Tri(ethoxy/methoxy)silyl]propyl]urea; N-(Triethoxysilylpropyl)urea cas no : 23779-32-0

Nom INCI : ACETYL CYSTEINE Nom chimique : Acetylcysteine N° EINECS/ELINCS : 210-498-3 Ses fonctions (INCI) Antioxydant : Inhibe les réactions favorisées par l'oxygène, évitant ainsi l'oxydation et la rancidité Agent d'entretien de la peau : Maintient la peau en bon état

Nom INCI : ACETYL GLUTAMIC ACID Nom chimique : N-acetylglutamic acid N° EINECS/ELINCS : 214-708-4 Ses fonctions (INCI) Agent d'entretien de la peau : Maintient la peau en bon état

Nom INCI : ACETYL TRIETHYL CITRATE Nom chimique : Triethyl 2-acetoxy-1,2,3-propanetricarboxylate N° EINECS/ELINCS : 201-066-5 Ses fonctions (INCI) Agent filmogène : Produit un film continu sur la peau, les cheveux ou les ongles Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques

Nom INCI : ACETYL TRIETHYLHEXYL CITRATE Nom chimique : Tris(2-ethylhexyl) 2-(acetyloxy)propane-1,2,3-tricarboxylate N° EINECS/ELINCS : 205-617-0 Ses fonctions (INCI) Emollient : Adoucit et assouplit la peau Agent filmogène : Produit un film continu sur la peau, les cheveux ou les ongles Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée Agent d'entretien de la peau : Maintient la peau en bon état

Nom INCI : ACETYLATED LANOLIN N° EINECS/ELINCS : 262-979-2 Ses fonctions (INCI) Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface Emollient : Adoucit et assouplit la peau Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Conditionneur capillaire : Laisse les cheveux faciles àcoiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance Agent d'entretien de la peau : Maintient la peau en bon état

Acetylcitric Acid, Tributyl Ester;2-acetyltributylcitrate; Acetyl Butyl Citrate; Acetyl Tributyl Citrate; Tributyl 2-(Acetyloxy)-1,2,3-propanetricarboxylate; 1,2,3-propanetricarboxylic Acid, 2-(Acetyloxy)-, Tributyl Ester; Tributyl Acetylcitrate; Tributyl Citrate Acetate; Tributyl O-acetylcitrate; O-acetilcitrato de tributilo; O-acétylcitrate de tributyle; 2-acetoxy-1,2,3-propanetricarboxylic Acid Tributyl Ester; Tributyl 2-acetoxy-1,2,3-propanetricarboxylate; cas no: 77-90-7

ACIDE GLYOXYLIQUE; GLYOXYLIC ACID, N° CAS : 298-12-4, Nom INCI : GLYOXYLIC ACID, Nom chimique : Glyoxylic acid, N° EINECS/ELINCS : 206-058-5. Ses fonctions (INCI): Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Régulateur de pH : Stabilise le pH des cosmétiques. Agent bouclant ou lissant (coiffant) : Modifie la structure chimique des cheveux, pour les coiffer dans le style requis. Noms français : ACIDE GLYOXYLIQUE. Noms anglais : ACETIC ACID, OXO-; GLYOXYLIC ACID. 1209322 [Beilstein]; 201-180-5 [EINECS]; 2-Hydroxyethanoic acid; 79-14-1 [RN]; Acetic acid, 2-hydroxy- [ACD/Index Name]; Acide glycol [French] [ACD/IUPAC Name]; Acide hydroxyacétique [French]; a-Hydroxyacetic acid Glycol acid [ACD/IUPAC Name]; Glycolsäure [German]; Hydroxyessigsäure [German] [ACD/IUPAC Name]; Kyselina glykolova [Czech]; Kyselina hydroxyoctova [Czech]; QV1Q [WLN] 1,2-Ethanediol [ACD/Index Name]; 102962-28-7 [RN]; 1-hydroxy-ethanoic acid; 26009-03-0 [RN]; 2-oxonioacetate; 4-03-00-00571 (Beilstein Handbook Reference) [Beilstein];Acetate ion Acetic acid [ACD/Index Name] [ACD/IUPAC Name]; D(-)-TARTARIC ACID; D-malate; EDO; GLV; Glycocide; Glycolic acid, 66-70% aqueous solution; glycolic acid, crystal, reagent;Glycolic acid, pure, 99.5%; Glycollic acid; Glyoxylic acid [Wiki]; GOA; HOCH2COOH; Hydroxy-acetic acid; Hydroxyethanoic acid; Kyselina glykolova; MFCD00868116 [MDL number]; MLT; TAR;WLN: QV1Q α-Hydroxyacetic acid; α-Hydroxyacetic acid; 乙醇酸 [Chinese]. Glyoxylic acid. CAS names; Acetic acid, 2-oxo-. : 2-oxo acetic acid; 2-oxoacetic acid; glyocylic acid; glyoxyl acid ; Glyoxylic Acid (ca. 50% in Water, ca. 9mol/L); Glyoxylic Acid 50% (aqueous solution); oxaldehydic acid; oxoacetic acid; oxoethanoic acid. Trade names: Glyoxylic acid 50 % (aqueous solution); Glyoxylic acid liq 50

Lanolin acetyl ester; Acetyl ester of lanolin; cas no: 61788-48-5

Acetylsalicylic Acid; ASPIRIN; 2-(acetyloxy)-Benzoic acid; Solpyron; Ecotrin; Colfarit; Asatylin; Acetophen; Acetosal; Rhodine; o-Acetoxybenzoic Acid; Extren; Benaspir; Entericin; Bialpirinia; Contrheuma Retard; Salicylic Acid Acetate; Acetylsalicylsaure (German); Acido Acetilsalicilico (Italian); Acimetten; Acide Acetylsalicylique (French); Acido o-Acetil-benzoico (Italian); 2-Acetoxybenzoova; Kyselina Acetylsalicylova cas no: 50-78-2

1-(4-Hydroxyphenyl)ethanone; 4-Acetylphenol; Piceol; 4'-hidroxiacetofenona (Spanish); 4'-hydroxyacétophénone (French); p-Hydroxyphenyl Methyl Ketone; cas no : 99-93-4

achillea millefolium extract; extract of the leaves and flowers of the yarrow, achillea millefolium l., asteraceae; milfoil extract; yarrow extract CAS NO:84082-83-7

Prunus Amygdalus Dulcis Fruit Extract; almond fruit extract; prunus dulcis fruit extract; amygdalus communis linn. var. dulcis fruit extract cas no:90320-37-9

hot pepper flavor; pepper flavor (hot)

Bitter Sophora Kökü Ekstraktı CNAS ve USDA Organik ile buluşuyor.
Acı Sofora Kökü Ekstraktının raf ömrü 2 yıldır.


CAS Numarası: 5041-82-7
EC Numarası: 225-649-4
Latince adı: Sophora flavescens Ait
INCI İsimleri: SOPHORA FLAVESCENS KÖK EKSTRAKTI
Moleküler Formül: C15H24N2O



EŞ ANLAMLILAR:
Sophora flavescens Kök Özü, Ku Shen Özü, Ku Shen Kök Özü, Flavescent Sophora Kök Özü, Acı Sophora Özü, Kushen Özü, Sophora Özü, Sophora Kök Özü



Acı Sophora Kökü Ekstraktı anti-bakteriyel ve anti-inflamatuar etki gösterir.
Acı Sophora Kökü Ekstraktı matrin ve oksimatrin gibi alkaloitler içerir.
Acı Sophora Kökü Ekstraktı iç ısısını hafifletir ve tümörleri baskılar.


Acı Sophora Kökü Ekstraktı kozmetik ürünlerinin formülasyonunda uygulama alanı bulmaktadır.
Acı Sophora Kökü Ekstraktı CNAS ve USDA Organik ile buluşuyor.
Acı Sophora Kökü Ekstraktının raf ömrü 2 yıldır.


Acı Sophora Kökü Ekstraktı yaklaşık bir düzine alkaloit içerir, bunlardan en yüksek olanları matrin ve oksimatrindir ve kurutulmuş kök stoğunun yaklaşık %2'sini oluştururlar (çoğu oksimatrin formundadır), ardından yakından ilişkili alkaloitler gelir: esas olarak sofokarpin, ancak ayrıca az miktarda Sophoranol, Sophoramin, soforidin, allomatrin, izomatrin ve diğerleri.


Bu alkaloitler ilk olarak 1958-1978 yılları arasında yapılan bir dizi yayında kushen'in bileşenleri olarak bildirilmiştir.
Genel olarak klinik olarak uygulanan Sophora alkaloitlerinin dozajı günde 400-600 mg aralığındadır.


Çincede “acı kök” anlamına gelen Acı Sophora Kökü Ekstraktı veya Sophora flavescens veya Ku Shen, Geleneksel tıpta çok çeşitli semptomları tedavi etmek için kullanılan ve kalp, karaciğer, bağırsak yolu ve cilt üzerinde iddia edilen etkilere sahip bir bitkidir.


Acı Sophora Kökü Ekstraktı, Ku Shen veya Sophora kökü olarak da bilinen Sophora flavescens bitkisinin köklerinden elde edilen doğal bir ekstrakttır.
Acı Sophora Kökü Ekstraktı, yüzyıllardır geleneksel tıp uygulamalarında kullanılan geleneksel bir Çin bitkisel ilacıdır.



ACI SOPHORA KÖKÜ EKSTRAKTININ KULLANIMI ve UYGULAMALARI:
Acı Sophora Kökü Ekstraktının Kullanımı: Kozmetik, Gıda, Sağlık Bakım Ürünleri, Tıpta kullanılır.
Acı Sophora Kökü Ekstraktı, baklagiller familyasından matrine cinsinden bir bitki olan Sophora flavescens'ten elde edilen bir alkaloiddir.
Acı Sophora Kökü Ekstraktı sert, kesiti iri lifli, sarı beyaz renktedir.


Acı Sophora Kök Ekstraktının kokusu hafif, tadı ise acımsıdır.
Acı Sophora Kökü Ekstraktının Kullanımı: Gıda, Sağlık Bakım Ürünleri, Tıp, Kozmetikte kullanılır.


Acı Sophora Kökü Ekstraktı beyazlatıcı, iltihap giderici, akne karşıtı, antibakteriyel ve diğer etkilere sahip olup, yüzyıllar önce güzellik ve cilt bakımında kullanılmış olup, günümüzde başlıca kozmesötik tercih edilen kozmetik hammaddesidir.


-Acı Sophora Kökü Ekstraktının Tarımsal Uygulamaları:
Tarımda kullanılan deniz pestisiti aslında Acı Sophora Kökü Ekstraktından elde edilen tüm maddeleri ifade eder.
Acı Sophora Kökü Ekstraktı tarımda yaygın olarak kullanılır ve iyi bir kontrol etkisine sahiptir.

Acı Sophora Kökü Ekstraktı düşük toksik, düşük kalıntı içeren ve çevre dostu bir pestisittir.
Acı Sophora Kökü Ekstraktı özellikle çam tırtılları, çay tırtılları ve lahana tırtılları gibi çeşitli zararlıları kontrol altına alır.
Acı Sophora Kökü Ekstraktının böcek öldürücü aktivite, bakteri öldürücü aktivite ve bitki büyüme fonksiyonunun düzenlenmesi gibi birçok fonksiyonu vardır.



ACI SOPHORA KÖKÜ EKSTRAKTININ FAYDALARI NELERDİR?
Acı Sophora Kökü Ekstraktı esas olarak alkaloitler, flavonoidler, kinonlar ve triterpenoid saponinler içerir.
Alkaloitler arasında matrin, oksimatrin, soforidin, Sophoranol, Sophoramin vb. bulunur.
Modern farmakolojik çalışmalar, Acı Sophora Kökü Ekstraktının esas olarak matrin ve çeşitli alkaloitler içerdiğini ve farmakolojik etkilerinin aşağıdaki gibi olduğunu göstermiştir:

1. Anti-tümör
Yapılan araştırmalarda Acı Sophora Kökü Ekstraktının antikanser aktivitesi gösterdiği ve kanser hücreleri üzerinde farklı derecelerde inhibisyon etkisi gösterdiği ortaya konmuştur.

2. Anti-alerji
Acı Sophora Kökü Ekstraktı, anti-tümör etkilerinin yanı sıra alerjik medyatörlerin salınımını da azaltarak bağışıklık baskılayıcı etki göstererek anti-alerjik etki gösterir.

3. Antibakteriyel
Farmakolojik çalışmalar, Acı Sophora Kökü Ekstraktındaki diğer alkaloitlerin bakteriyel solunum ve nükleik asit metabolizması üzerinde inhibe edici etkilere sahip olduğunu ve Shigella, Proteus ve Staphylococcus aureus üzerinde belirli inhibe edici etkilere sahip olduğunu göstermiştir.

4. Solucan İlacı
Acı Sophora Kökü Ekstraktının solucan düşürücü etkisi, parazitin sinir sistemini felç edebilen ve sonuçta böceğin vücudunun yapışmasını ve canlılığını kaybetmesine neden olan ve metabolik atıklarla birlikte dışarı atılarak solucan düşürücü etki sağlayan alkaloit bileşeninden de yararlanır.



ACI SOPHORA KÖKÜ EKSTRAKTININ İŞLEVİ:
*Sağlık Takviyesi
*Antienflamatuvar
*Böcek ilacı



ACI SOPHORA KÖKÜ EKSTRAKTININ İŞLEVİ NEDİR?
1. Isıyı giderme ve nemi kurutma:
Acı Sophora Kökü Ekstraktı, Matrine ile benzer etkiye sahiptir.
Acı Sophora Kökü Ekstraktının acı tadı, soğuk yapısı, kalp, karaciğer ve mesane kanallarına girerek vücuttaki sıcak havayı temizler, idrar söktürücü ve nem giderici etkisi vardır.

2. Böcek ilacı:
Acı Sophora Kökü Ekstraktı, bakteri ve trikomoniyazisi inhibe edici etkiye sahip olduğundan, ıslak ve sıcak bölge, Yin şişliği ve Yin kaşıntısı, egzama ve yaralar gibi hastalıklarda kesin bir tedavi edici rol oynayabilir.

3. Güzellik:
Acı Sophora Kökü Ekstraktı, yağ dengeleyici, gözenekleri sıkılaştırıcı, cilt içindeki kirleri giderici etkiye sahiptir ve hücre onarımında ve güzelleşmesinde önemli rol oynar.

4.İltihap giderici:



ACI SOPHORA KÖKÜ EKSTRAKTININ FONKSİYONLARI VE UYGULAMALARI:
1. İlaçlarda Uygulanır: anti-bakteri, anti-inflamatuar;
2. İç ısıyı gidermek için; ve sarkom S180'i baskılamak için kullanılır, anti-tümörler;
3. Tarım alanında yaygın olarak uygulanır: (Düşük toksisite; yaban hayatı için güvenli)
• Matrin geniş spektrumlu pestisit insektisit olarak kullanılır;
• Zararlıları öldürmek için: kırmızı akar, pas akarı, lahana kurdu, lahana güvesi, yaprak madenci, çay geometrid, vb.;
• Bitkisel pestisit içeriklerinde yaygın olarak kullanılır.



ACI SOPHORA KÖKÜ EKSTRAKTININ İDDİALARI:
*Anti-inflamatuarlar
*Antimikrobiyaller
*biyo-bazlı



ACI SOPHORA KÖKÜ EKSTRAKTININ ÖZELLİKLERİ:
Acı Sophora Kökü Ekstraktı, isilik dizanterisi, sarılık, dışkıda kan, anüri, vajinal akıntı, vulva kaşıntısı, egzama, egzama, cilt kaşıntısı, cüzzam uyuz, trikomonal vajinitin harici tedavisinde kullanılır.



ACI SOPHORA KÖKÜ EKSTRAKTININ FİZİKSEL ve KİMYASAL ÖZELLİKLERİ:
Ürün Adı: Acı Sophora Kökü Ekstraktı
Botanik Adı: Sophora flavescens
Kullanılan Kısım: Kök
Özellikler: 4:1 5:1 8:1
CAS Numarası : 519-02-8
Moleküler Formül: C15H24N2O
Moleküler Ağırlık: 248.3639
Görünüm: Beyaz iğne kristali
Latince Adı:Sophora flavescens
Görünüm: Beyaz Toz
Özellikler/Etkin İçerikler: Matrine98%
Sertifikalar: HELAL, KOSHER, ISO22000, SC, BRC (ORGANİK)
Kullanılan Parça ： Kök

Ana bileşenler:Matrinler
Formül: C15H24N2O
Özellikler:4:1 5:1 8:1
Tespit: HPLC
INCI İsimleri: SOPHORA FLAVESCENS KÖK EKSTRAKTI
Görünüm: Sarımsı kahverengi toz
Çözünürlük: Su ve alkolde çözünür
pH: 4.0-7.0 (çözeltide)
Yoğunluk: 1,2 g/cm³
Erime Noktası: Yaklaşık 190°C
Kaynama Noktası: Uygulanamaz (katı özüt)
Moleküler Formül: C15H24N2O
Moleküler Ağırlık: 248.36 g/mol



ACI SOPHORA KÖKÜ EKSTRAKTININ İLK YARDIM ÖNLEMLERİ:
-İlk yardım önlemlerinin tanımı
*Genel tavsiye:
Bu malzeme güvenlik bilgi formunu görevli doktora gösterin.
*Solunması halinde:
Teneffüs ettikten sonra:
Temiz hava aldırın.
*Cilt teması halinde:
Kirlenmiş tüm giysilerinizi derhal çıkarın.
Cildinizi durulayın
su/duş.
*Göz teması halinde:
Göz temasından sonra:
Bol su ile durulayın.
Göz doktorunu arayın.
Kontakt lenslerinizi çıkarın.
*Yutulması halinde:
Yuttuktan sonra:
Mağdura hemen su içirin (en fazla iki bardak).
Bir hekime danışın.
- Acil tıbbi müdahale ve özel tedavi gerektiğine dair gösterge.
Veri yok



ACI SOPHORA KÖKÜ EKSTRAKTININ YANLIŞLIKLA SALIVERİLME ÖNLEMLERİ:
-Çevresel önlemler:
Ürünün giderlere kaçmasına izin vermeyin.
-Sınırlama ve temizleme yöntemleri ve malzemeleri:
Giderleri kapatın.
Dökülenleri toplayın, bağlayın ve pompalayın.
Olası maddi kısıtlamalara dikkat edin.
Kuru olarak alın.
Uygun şekilde bertaraf edin.
Etkilenen bölgeyi temizleyin.



ACI SOPHORA KÖKÜ EKSTRAKTININ YANGINLA MÜCADELE ÖNLEMLERİ:
-Söndürme malzemeleri:
*Uygun söndürme ortamı:
Karbondioksit (CO2)
Köpük
Kuru toz
*Uygun olmayan söndürme maddeleri:
Bu madde/karışım için söndürme maddelerine ilişkin herhangi bir sınırlama verilmemiştir.
-Daha fazla bilgi:
Yangın söndürme sularının yüzey sularını veya yeraltı su sistemini kirletmesini önleyin.



ACI SOPHORA KÖKÜ EKSTRAKTININ MARUZİYET KONTROLLERİ/KİŞİSEL KORUNMA:
-Kontrol parametreleri:
--İşyeri kontrol parametreleri olan bileşenler:
-Pozlama kontrolleri:
--Kişisel koruyucu ekipman:
*Göz/yüz koruması:
Gözlerinizi korumak için ekipman kullanın.
Güvenlik gözlüğü kullanın
*Vücut Koruması:
koruyucu giysi giyin.
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L'acide (S) -2-hydroxysuccinique (acide L-malique) est presque inodore (parfois une légère odeur âcre) avec un goût acidulé et acide.
L'acide (S) -2-hydroxysuccinique (acide L-malique) est non piquant.
Peut être préparé par hydratation de l'acide (S)-2-hydroxysuccinique (acide L-malique) ; par fermentation àpartir de sucres.

CAS : 97-67-6
FM : C4H6O5
MW : 134,09
EINECS : 202-601-5

Synonymes
Acide L-(-)-malique, CP ;Acide butanedioïque, 2-hydroxy-, (2S)- ;pinguosuan ;Acide butanedioïque,hydroxy-,(S)- ;hydroxy-,(S)-acide butanedioïque ;l-(ii) -acide malique;acide L-Gydroxybutanedioïque;acide L-Mailcacid;97-67-6;acide L-malique;acide L-(-)-malique;acide (S)-2-hydroxysuccinique;acide (2S)-2-hydroxybutanedioïque;( Acide S)-malique;Acide L(-)-malique;(-)-Acide malique;Acide L-pomme;Acide L-hydroxybutanedioïque;Acide pomme;(-)-Acide hydroxysuccinique;L-malate;S-(-) -Acide malique;Acide S-2-hydroxybutanedioïque;Acide butanedioïque, hydroxy-, (2S)-;Acide malique, L-;Acide L-2-hydroxybutanedioïque;CHEBI:30797;(-)-Acide L-malique;(S )-malate;MFCD00064213;Acide malique forme L-(-);Acide hydroxysuccinnique (-);Acide L-hydroxysuccinique;J3TZF807X5;(S)-(-)-Acide hydroxysuccinique;CHEMBL1234046;NSC9232;(S)-(- )-2-Hydroxysuccinique;NSC-9232;NSC 9232;Acide butanedioïque, 2-hydroxy-, (2S)-;(S)-Acide hydroxybutanedioïque;(-)-(S)-Acide malique;Acide hydroxybutanedioïque, (- )-;UNII-J3TZF807X5;acide malique;Acide hydroxybutanedioïque, (S)-;2yfa;4elc;4ipi;4ipj;L-Hydroxysuccinate;Acide 2-hydroxybutanedioïque, (S)-;(2s)-acide malique;EINECS 202 -601-5;L-Hydroxybutanedioate;nchembio867-comp7;L-(-)acide malique;(-)-Hydroxysuccinate;L-(-)-Acide de pomme;S-(-)-Malate;(S)-Hydroxybutanedioate; S-2-Hydroxybutanedioate;(-)-(S)-Malate;(S)-(-)-acide malique;(S)-hydroxy-Butanedioate;(S)-Hydroxysuccinique;ACIDE L(-)MALIQUE;( Acide S)-2-hydroxysuccinique;bmse000238;ACIDE MALIQUE [HSDB];ACIDE MALIQUE, (L);(S)-(-)-Hydroxysuccinate;ACIDE L-MALIQUE [FHFI];Acide (S)-hydroxy-butanedioïque;SCHEMBL256122 ;ACIDE L-MALIQUE [WHO-DD];ACIDE MALIQUE, L-[II];acide (-)-(s)-hydroxybutanedioïque;DTXSID30273987;acide (2S)-(-)-hydroxybutanedioïque;AMY40197;HY-Y1069; BDBM50510127;s6292;AKOS006346693;CS-W020132;ACIDE MALIQUE L-(-)-FORM [MI];Acide L-(-)-Malique, BioXtra, >=95%;AS-18628;L-(-)-Malic acide, >=95% (titrage);(S)-E 296
;(-)-1-Hydroxy-1,2-éthanedicarboxylique;M0022;NS00068391;EN300-93424;C00149;L-(-)-Acide malique, pur, >=99,0 % (T);L-(-) -Acide malique, ReagentPlus(R), >=99 %;M-0850;35F9ECA9-BBE6-463D-BF3F-275FACC5D14E;L-(-)-Acide malique, qualité spéciale SAJ, >=99,0 %;L-(- )-Acide malique, qualité réactif Vetec(TM), 97 % ; pureté ee : 99 % (GLC);Acide L-(-)-malique, matériau de référence certifié, TraceCERT(R);Acide L-(-)-malique, BioReagent, adapté àla culture cellulaire, adapté àla culture de cellules d'insectes ;26999 -59-7

Une forme optiquement active d'acide (S)-2-hydroxysuccinique (acide L-malique) ayant une configuration (S).
L'acide (S)-2-hydroxysuccinique (acide L-malique) est un acide organique que l'on trouve couramment dans le vin.
L'acide (S)-2-Hydroxysuccinique (acide L-Malique) joue un rôle important dans la stabilité microbiologique du vin.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est un composé organique de formule moléculaire HO2CCH(OH)CH2CO2H.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est un acide dicarboxylique fabriqué par tous les organismes vivants, qui contribue au goût aigre des fruits et est utilisé comme additif alimentaire.
L'acide (S) -2-hydroxysuccinique (acide L-malique) a deux formes stéréoisomères (énantiomères L et D), bien que seul l'isomère L existe naturellement.
Les sels et esters de l’acide (S)-2-hydroxysuccinique (acide L-malique) sont appelés malates.
L'anion malate est un intermédiaire métabolique dans le cycle de l'acide citrique.

Biochimie
L'acide (S)-2-hydroxysuccinique (acide L-malique) est la forme naturelle, tandis qu'un mélange d'acide L- et D-malique est produit synthétiquement.
L'acide (S) -2-hydroxysuccinique (acide L-malique) joue un rôle important en biochimie.
Dans le processus de fixation du carbone C4, le malate est une source de CO2 dans le cycle de Calvin.
Dans le cycle de l'acide citrique, l'acide (S)-2-hydroxysuccinique (acide L-malique) est un intermédiaire, formé par l'ajout d'un groupe -OH sur la face si du fumarate.
L'acide (S) -2-hydroxysuccinique (acide L-malique) peut également être formé àpartir du pyruvate via des réactions anaplérotiques.

L'acide (S)-2-hydroxysuccinique (acide L-malique) est également synthétisé par la carboxylation du phosphoénolpyruvate dans les cellules de garde des feuilles des plantes.
Le malate, en tant qu'anion double, accompagne souvent les cations potassium lors de l'absorption des solutés dans les cellules de garde afin de maintenir l'équilibre électrique dans la cellule.
L'accumulation de ces solutés dans la cellule de garde diminue le potentiel de soluté, permettant àl'eau de pénétrer dans la cellule et favorisant l'ouverture des stomates.

Acide (S)-2-hydroxysuccinique (acide L-malique) Propriétés chimiques
Point de fusion : 101-103 °C (lit.)
Alpha : -2 º (c=8,5, H2O)
Point d'ébullition : 167,16°C (estimation approximative)
Densité : 1,60
Pression de vapeur : 0Pa à25℃
FEMA : 2655 | ACIDE L-MALIQUE
Indice de réfraction : -6,5° (C=10, Acétone)
Fp : 220 °C
Température de stockage : Conserver en dessous de +30°C.
Solubilité H2O : 0,5 M à20 °C, clair, incolore
Forme : Poudre
Couleur blanche
Gravité spécifique : 1,595 (20/4 ℃)
Odeur : inodore
PH : 2,2 (10 g/l, H2O, 20 ℃)
pka : (1) 3,46, (2) 5,10 (à25 ℃)
Type d'odeur : inodore
Activité optique : [α]20/D 30±2°, c = 5,5% dans la pyridine
Solubilité dans l'eau : soluble
Merck : 14 5707
Numéro JECFA : 619
Numéro de référence : 1723541
InChIKey : BJEPYKJPYRNKOW-REOHCLBHSA-N
LogP : -1,68
Référence de la base de données CAS : 97-67-6 (référence de la base de données CAS)
Référence chimique NIST : Acide (S)-2-hydroxysuccinique (acide L-malique) (97-67-6)
Système d'enregistrement des substances de l'EPA : Acide (S)-2-hydroxysuccinique (acide L-malique) (97-67-6)

L'acide (S) -2-hydroxysuccinique (acide L-malique) est presque inodore (parfois une légère odeur âcre).
L'acide (S) -2-hydroxysuccinique (acide L-malique) a un goût acidulé, acide et non piquant.

Les usages
L'acide (S) -2-hydroxysuccinique (acide L-malique) est utilisé comme additif alimentaire, réactif protecteur sélectif α-amino pour les dérivés d'acides aminés.
Synton polyvalent pour la préparation de composés chiraux, notamment les agonistes des récepteurs κ-opioïdes, l'analogue de la 1α,25-dihydroxyvitamine D3 et la phoslactomycine B.
L'isomère naturel est la forme L que l'on trouve dans les pommes et dans de nombreux autres fruits et plantes.
Réactif sélectif de protection α-amino pour les dérivés d’acides aminés.
Synton polyvalent pour la préparation de composés chiraux, notamment la réception κ-opioïde
Intermédiaire en synthèse chimique.
Agent chélatant et tampon.
Agent aromatisant, exhausteur de goût et acidulant dans les aliments.

L'acide (S)-2-hydroxysuccinique (acide L-malique) contient des ingrédients émollients naturels, qui peuvent éliminer les rides àla surface de la peau, rendre la peau tendre et blanche, lisse et élastique, donc privilégiée dans la formule cosmétique ; L'acide L-malique peut être formulé avec une variété de saveurs, d'épices, pour une variété de produits chimiques quotidiens, tels que le dentifrice, le shampoing, etc. L'acide (S)-2-hydroxysuccinique (acide L-malique) est utilisé àl'étranger pour remplacer l'acide citrique en tant que nouveau type d'additif détergent pour la synthèse de détergents spéciaux de haute qualité.
L'acide (S) -2-hydroxysuccinique (acide L-malique) peut être utilisé dans des préparations pharmaceutiques, des comprimés, des sirops, peut également être mélangé àla solution d'acides aminés, peut améliorer considérablement le taux d'absorption des acides aminés ; L'acide (S)-2-hydroxysuccinique (acide L-malique) peut être utilisé pour le traitement des maladies du foie, de l'anémie, de la faible immunité, de l'urémie, de l'hypertension, de l'insuffisance hépatique et d'autres maladies, et peut réduire l'effet toxique des médicaments anticancéreux sur la santé normale. cellules; Peut également être utilisé pour la préparation et la synthèse d'insectifuges, d'agents antitartre.
De plus, l'acide (S)-2-hydroxysuccinique (acide L-malique) peut également être utilisé comme agent de nettoyage industriel, agent de durcissement de résine, plastifiant de matière synthétique, additif alimentaire, etc.

Dans la nourriture
L'acide (S)-2-hydroxysuccinique (acide L-malique) a été isolé pour la première fois du jus de pomme par Carl Wilhelm Scheele en 1785.
Antoine Lavoisier a proposé en 1787 le nom acide malique, dérivé du mot latin pour pomme, mālum, tout comme son nom de genre Malus.
En allemand, l'acide (S)-2-hydroxysuccinique (acide L-malique) est nommé Äpfelsäure (ou Apfelsäure) d'après le pluriel ou le singulier d'une substance aigre provenant de la pomme, mais le(s) sel(s) sont appelés Malat(e).
L'acide malique est le principal acide présent dans de nombreux fruits, notamment les abricots, les mûres, les myrtilles, les cerises, les raisins, les mirabelles, les pêches, les poires, les prunes et les coings, et est présent en concentrations plus faibles dans d'autres fruits, comme les agrumes.
L'acide (S)-2-hydroxysuccinique (acide L-malique) contribue àl'acidité des pommes non mûres.
Les pommes aigres contiennent des proportions élevées d’acide.
L'acide (S)-2-Hydroxysuccinique (acide L-Malique) est présent dans les raisins et dans la plupart des vins avec des concentrations parfois aussi élevées que 5 g/L.
L'acide (S)-2-Hydroxysuccinique (acide L-Malique) confère un goût acidulé au vin ; la quantité diminue avec l'augmentation de la maturité des fruits.
Le goût de l'acide (S)-2-Hydroxysuccinique (acide L-Malique) est très clair et pur dans la rhubarbe, plante dont il est l'arôme principal.
L'acide (S) -2-hydroxysuccinique (acide L-malique) est également le composé responsable de la saveur acidulée de l'épice sumac.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est également un composant de certains arômes artificiels de vinaigre, tels que les croustilles aromatisées « sel et vinaigre ».

Le processus de fermentation malolactique convertit l’acide malique en acide lactique beaucoup plus doux.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est présent naturellement dans tous les fruits et de nombreux légumes et est généré dans le métabolisme des fruits.
L'acide (S)-2-hydroxysuccinique (acide L-malique), lorsqu'il est ajouté aux produits alimentaires, est désigné par le numéro E E296.
L'acide (S) -2-hydroxysuccinique (acide L-malique) est parfois utilisé avec ou àla place de l'acide citrique moins acide dans les bonbons aigres.
Ces bonbons sont parfois étiquetés avec un avertissement indiquant qu'une consommation excessive peut provoquer une irritation de la bouche.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est approuvé pour une utilisation comme additif alimentaire dans l'UE, aux États-Unis, en Australie et en Nouvelle-Zélande (où il est répertorié sous son numéro SIN 296).
L'acide (S)-2-hydroxysuccinique (acide L-malique) contient 10 kJ (2,39 kilocalories) d'énergie par gramme.

Production et principales réactions
L'acide racémique (S)-2-hydroxysuccinique (acide L-malique) est produit industriellement par la double hydratation de l'anhydride maléique.
En 2000, la capacité de production américaine était de 5 000 tonnes par an.
Les énantiomères peuvent être séparés par résolution chirale du mélange racémique.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est obtenu par fermentation de l'acide fumarique.
L'autocondensation de l'acide malique en présence d'acide sulfurique fumant donne l'acide pyrone coumalique :

2 HO2CCH(OH)CH2CO2H → HO2CC4H3O2 + 2 CO + 4 H2O
Du monoxyde de carbone et de l'eau sont libérés lors de cette réaction.
L'acide (S) -2-hydroxysuccinique (acide L-malique) a joué un rôle important dans la découverte de l'inversion de Walden et du cycle de Walden, dans lesquels l'acide (-) -malique est d'abord converti en acide (+) -chlorosuccinique par action du phosphore. pentachlorure.
L'oxyde d'argent humide convertit ensuite le composé chloré en acide (+)-malique, qui réagit ensuite avec PCl5 pour donner l'acide (-)-chlorosuccinique.
Le cycle est terminé lorsque l'oxyde d'argent ramène ce composé àl'acide (-)-malique.
L'acide (S)-2-hydroxysuccinique (acide L-malique) est utilisé pour résoudre l'α-phényléthylamine, un agent de résolution polyvalent àpart entière.

Préparation
(1) une solution mixte de L-malate et de fumarate a été préparée selon la méthode de transformation cellulaire de l'art antérieur (DE3310849).
La souche d'aspergilus goneii isolée du sol a été traitée avec du sucre 30g/L, de l'hydrogénophosphate diammonique 3G/L, du sulfate d'ammonium 2G/L, du chlorure de potassium 2G/L, du sulfate de magnésium 1g/L, les cellules ont été cultivées dans un milieu de culture contenant 5g /L de fumarate de sodium pendant 48 heures et séparé par filtration.
Préparez une solution de carraghénane à2 % à60-70 ℃ et ajoutez les cellules séparées à10 % (p/p) lors du refroidissement à50 ℃, remuez uniformément puis versez dans une plaque pour solidifier, des cellules immobilisées de 5 mm X 5 mm X 5 mm ont été préparées. .
Une colonne de verre de 8 cm x 60 cm a ensuite été chargée.

Une solution de fumarate de sodium 1,4 m a été passée àtravers la colonne de cellules immobilisées àun débit de 1 000 ml/h pour obtenir une solution mixte de L-malate et de fumarate.
(2) prélever 1 000 ml du mélange obtenu àl'étape (1), qui contient 186 g de L-malate de sodium et 56 g de fumarate de sodium.
La solution a été chauffée à60 °C et du G (rapport molaire 1,05 : 1) d'acide fumarique a été ajouté sous agitation.
La réaction a été agitée pendant 3,5 heures, pH = 3,2, refroidie à15 ~ 20 ° C, filtrée, le gâteau de filtration a été lavé avec une petite quantité d'eau puis neutralisé avec NaOH àpH = 7-8 pour la transformation cellulaire.

Le filtrat résultant était de 980 ml et contenait 40 g de fumarate monosodique.
Chauffer à85 °c, passer sur une colonne échangeuse de cations d'acide fort ml 001x7 (diamètre 6 cm, hauteur 60 cm), récupérer l'éluant et concentrer l'acide (S)-2-Hydroxysuccinique (acide L-Malique) sous pression réduite, lorsque le L-malique la concentration d'acide est augmentée à40 %, après refroidissement à10-15 °C, l'acide fumarique a été récupéré par filtration.
Le filtrat est ensuite concentré sous pression réduite jusqu'àune concentration en acide (S)-2-hydroxysuccinique (acide L-malique) de 80 à82 %, refroidi à15 °C.
Pour cristalliser 91gL-acide malique.
La liqueur mère contient 46 gL d'acide malique et la liqueur mère peut être recyclée.
Le rendement en acide (S)-2-Hydroxysuccinique (acide L-Malique) correspond à97 %.

Méthodes de purification
Cristalliser l'acide (S)-2-hydroxysuccinique (acide L-malique) àpartir d'acétate d'éthyle/éther de pétrole (b 55-56o), en maintenant la température en dessous de 65o.
Ou dissolvez-le au reflux dans quinze parties d'éther diéthylique anhydre, décantez, concentrez au tiers du volume et cristallisez l'acide (S)-2-hydroxysuccinique (acide L-malique) à0°, àplusieurs reprises jusqu'àun point de fusion constant.

Acide 2-aminoéthanesulfinique; N° CAS : 300-84-5; Hypotaurine; Nom INCI : AMINOETHANESULFINIC ACID. Nom chimique : Ethanesulfinic acid, 2-amino-. Ses fonctions (INCI): Antioxydant : Inhibe les réactions favorisées par l'oxygène, évitant ainsi l'oxydation et la rancidité. Agent réducteur : Modifie la nature chimique d'une autre substance en ajoutant de l'hydrogène ou en éliminant l'oxygène. 2-amino-Ethanesulfinic acid; 2-Aminoethanesulfinic acid ; 2-Aminoethansulfinsäure [German] ; 2-Aminoethylsulfinate; 2-Aminoethylsulfinic acid; 300-84-5 [RN]; Acide 2-aminoéthanesulfinique [French] ; Ethanesulfinic acid, 2-amino- ; Hypotaurine; MFCD00038197; 2-amino-Ethanesulfinate 2-Aminoethanesulfinate ; Cystaminesulfinate; Cystaminesulfinic acid; 2-aminoethane-1-sulfinic acid; 2-aminoethanesulfinicacid; 2-azaniumylethane-1-sulfinate; 2-azaniumylethanesulfinate; 2-mmonioethane-1-sulfinate; hypotaurine zwitterion; Hypotaurine; 2-Aminoethylsulfinic acid; 2-Amino-ethanesulfinic acid; Lopac0_000573. Product Uses3,4 2-Amino-2-ethyl-1,3-propanediol is useful in a variety of applications, such as: Paints – as a dispersant for pigments, offering improved flow characteristics, stable pH values, low odor, and improved color; Additives – to control alkalinity and the release of excess formaldehyde in certain industrial situations, such as metal-working fluids; A chemical intermediate – to produce fatty acid emulsifiers (several industrial applications), oxazoline chemicals (surface-active compounds) and oxazolidine (cross-linkers in thermosetresins)

L'acide maléique homopolymère est un antitartre très efficace pour le carbonate de calcium, montrant d'excellentes performances àhaute température ainsi que dans les systèmes d'eau de refroidissement fortement alcalins.
En raison de ses bonnes propriétés d'inhibition du tartre et de tolérance aux hautes températures, l'acide maléique homopolymère est utilisé dans les usines de dessalement de l'eau.
L'acide maléique homopolymère a de meilleures performances lorsqu'il est combiné avec des phosphonates que lorsqu'ils sont utilisés seuls.

Numéro CAS : 26099-09-2
Numéro CE : 607-861-7
Formule moléculaire : C4H4O4;HOOCCH=CHCOOH;C4H4O4
Poids moléculaire : 116,07 g/mol

Synonymes: Acide 2-butènedioïque (2Z)-, homopolymère, Acide 2-butènedioïque (Z)-, homopolymère, Accent T 1107, Acumer 4200, Aron A 6510, Prémélange Bel 200, Belclène 200, Belclène 200LA, Belclène 710, Dequest P 9000, Dp 3328, Hpma, Anhydride polymaléique hydrolysé, Anhydride polymaléique hydrolysé, Anhydride polymaléique hydrolysé, Homopolymère d'acide maléique, Polymère d'acide maléique, Acide maléique, polymères, Nonpol PMA 50W, Nonpol PWA 50W, Acide polymaléique, Acide polymaléiqueAq, 150 shillings, HPMA, Acide polymaléique, Acide polymaléiqueAq, Poly(acide maléique), POLY(ACIDE MALÉIQUE), POLYMÈRE D'ACIDE MALÉIQUE, Acdi maléique (homopolymère), Anhydride polymaléique hydrolysé, Anhydride polymaléique hydrolysé, Anhydride polymaléique hydrolysé, anhydride polymaléique hydrolysé, Homopolymère d'acide (z)-2-butènedioïque

L'acide maléique homopolymère est l'homopolymère de l'acide maléique.
L'acide maléique homopolymère est un antitartre au carbonate de calcium très efficace qui présente d'excellentes performances dans les systèmes d'eau de refroidissement àhaute température et fortement alcalins.

L'acide maléique homopolymère est stable en présence de chlore ou d'autres biocides oxydants.
En raison de la bonne inhibition de l'échelle de l'acide maléique homopolymère et de ses propriétés de tolérance aux températures élevées, l'acide maléique homopolymère est utilisé dans les usines de dessalement de l'eau.
L'acide maléique homopolymère agit également comme inhibiteur de corrosion lorsqu'il est combiné avec des sels de zinc.

L'acide maléique homopolymère est un homopolymère d'acide maléique, avec une inhibition de seuil évidente et une modification cristalline, et un poids moléculaire moyen d'environ 1000.
L'acide maléique homopolymère est l'inhibiteur de carbonate de calcium supérieur dans les conditions d'eau sévères de dureté élevée, d'alcalinité élevée et de température élevée et un agent de support de formulation multifonctionnel dans les systèmes d'eau industriels et d'autres applications connexes.

L'acide maléique homopolymère est largement utilisé dans les usines de dessalement des équipements de vaporisation flash, des chaudières basse pression, des locomotives àvapeur, de l'évaporation du pétrole brut, des oléoducs et des systèmes industriels d'eau froide àcirculation.

L'acide maléique homopolymère a de meilleures performances lorsqu'il est combiné avec des phosphonates que lorsque les phosphonates sont utilisés seuls.
L'acide maléique homopolymère est compatible avec les composés d'ammonium quaternaire, bien qu'il ne soit pas affecté par le chlore ou d'autres biocides oxydants dans des conditions d'utilisation normales.

L'acide maléique homopolymère est un composé organique de type acide polycarboxylique, qui résiste aux températures élevées et peut chélater le calcium, le magnésium, le fer, etc. dans l'eau.
Bonne stabilité thermique, utilisation de la gamme PH, large dureté de l'eau, est un excellent inhibiteur de tartre.

L'acide maléique homopolymère, en tant qu'agent de traitement de l'eau verte àfaible coût et excellent, est devenu un membre important de l'inhibiteur et du dispersant de tartre soluble dans l'eau àhaute efficacité.
En particulier dans des conditions environnementales difficiles telles qu'une température élevée, un pH élevé, une alcalinité élevée, une dureté élevée, etc., l'acide maléique homopolymère a un effet significatif d'inhibition du tartre sur le carbonate de calcium, le sulfate de calcium, etc., qui ne sont pas des acides polypropylènes généraux et d'autres copolymérisation organique Le dispersant peut atteindre.
Dans le même temps, l'acide maléique homopolymère a une faible toxicité, aucun effet cancérigène et tératogène, et est souvent utilisé comme agent de traitement de l'eau pour faire circuler l'eau de refroidissement, l'eau de chaudière àbasse pression et le traitement anti-tartre pour l'injection d'eau dans les champs pétrolifères, le pétrole brut déshydratation et autres systèmes.

L'acide maléique homopolymère est un polyélectrolyte, également connu sous le nom d'agent antitartre H-1, l'acide maléique homopolymère, qui est produit par polyhydrolyse de l'anhydride maléique ou polymérisation par hydrolyse.
L'acide maléique homopolymère est un liquide visqueux brun-rouge àtempérature ambiante.

Facilement soluble dans l'eau, chaque atome de carbone de la chaîne polymère a une charge potentielle élevée.
Par conséquent, les propriétés du polyélectrolyte d'acide maléique homopolymère sont différentes de celles de l'acide polyacrylique ou de l'acide polyméthacrylique.

Lors d'une goutte avec LiOH, NaOH, KOH ou (CH3) 4NOH, seule la moitié du groupe carboxyle de l'acide total est neutralisée, et les propriétés sont différentes de l'acide polyacrylique ou de l'acide polyméthacrylique.
Lorsque la courbe LiOH, NaOH, KOH ou (CH3)4NOH est utilisée, il n'y a qu'un seul saut au point de demi-somme.

Par conséquent, en termes de titrage potentiométrique, l'acide maléique homopolymère est souvent considéré comme un acide unitaire.
Les homopolymères d'acide maléique et les copolymères d'acide maléique et d'acide acrylique peuvent être utilisés pour traiter les poudres de carbonate de calcium et de phosphate de calcium.

La modification de surface du carbonate de calcium permet d'améliorer la stabilité du carbonate de calcium en phase (système) organique ou inorganique, d'améliorer la dispersibilité de ces poudres en solution, et d'éviter l'agglomération des particules.
L'acide maléique homopolymère est préparé par polymérisation et hydrolyse de l'anhydride maléique sous l'action d'un catalyseur.
L'acide maléique homopolymère est principalement utilisé pour l'inhibition du tartre et de la corrosion des chaudières de locomotives àvapeur, des chaudières industrielles àbasse pression, des systèmes d'eau de refroidissement des moteurs àcombustion interne, du dessalement de l'eau de mer, de l'extraction du potassium de l'eau de mer, des systèmes d'échange de chaleur, des oléoducs des champs pétrolifères et des systèmes de retour des réservoirs.

L'acide maléique homopolymère est un médicament qui inhibe l'activité du maléate, du tartrate d'hydrogène et du chlorure de benzalkonium.
L'acide maléique homopolymère est utilisé comme inhibiteur actif dans le traitement des maladies infectieuses causées par des bactéries.

L'acide maléique homopolymère s'est avéré efficace contre les bactéries Gram-positives et Gram-négatives.
Les études de toxicité àlong terme sur les rats n'ont montré aucune preuve de cancérogénicité ou d'autres effets indésirables.
Il a également été démontré que l'acide maléique homopolymère se lie àla constante de vitesse pour les réactions en chaîne par polymérase, ce qui peut entraîner une inhibition de la croissance bactérienne.

L'acide maléique homopolymère est l'homopolymère de l'acide maléique.
L'acide maléique homopolymère est très stable en présence de chlore et d'autres biocides oxydants.

L'acide maléique homopolymère a de bonnes propriétés d'inhibition du tartre et de résistance aux hautes températures.
Par conséquent, l'acide maléique homopolymère peut être utilisé dans les usines de dessalement de l'eau.

L'acide maléique homopolymère est également un excellent antitartre au carbonate de calcium àhaute température et dans les systèmes d'eau de refroidissement hautement alcalins.
De plus, l'acide maléique homopolymère peut être utilisé en combinaison avec des sels de zinc comme inhibiteur de corrosion.

L'acide maléique homopolymère peut également être utilisé comme additif pour le béton et pour l'évaporation du pétrole brut.
L'acide maléique homopolymère peut être fabriqué par polymérisation de l'anhydride maléique I, un hydrocarbure aromatique, à60° à200° C.

Un polymère relativement homogène et facilement synthétisé, l'acide maléique homopolymère, a été étudié pour déterminer l'adéquation de l'acide maléique homopolymère en tant que composé modèle pour les substances humiques.
Les propriétés physiques et chimiques de l'acide maléique homopolymère ont été mesurées par spectroscopie UV/VIS, infrarouge àtransformée de Fourier et RMN 13C, chromatographie d'exclusion de taille àhaute pression et analyses élémentaires pour élucider les caractéristiques structurelles de l'acide maléique homopolymère et des substances humiques aquatiques.

En termes de taille, de polydispersité, de composition élémentaire et de spectres infrarouges, l'acide maléique homopolymère ressemble le plus aux acides fulviques dérivés principalement de sources terrestres.
L'absorptivité molaire (mesurée à280 nm) et les données spectroscopiques RMN 13C montrent cependant que l'acide maléique homopolymère présente nettement moins d'aromaticité que les matériaux fulviques de taille similaire.

En général, les acides fulviques aquatiques d'origine terrestre possèdent des pourcentages plus élevés de carbones aromatiques que l'acide maléique homopolymère ou les acides fulviques lacustres et souterrains.
Les spectres RMN 13C montrent également que les carbones aliphatiques II et acétal, présents dans plusieurs acides fulviques aquatiques, sont absents dans l'acide maléique homopolymère.

De plus, la teneur en carbone carboxylique de l'acide maléique homopolymère est significativement plus élevée que celle de tous les matériaux humiques utilisés dans cette étude.
Sur la base de ces résultats, l'acide maléique homopolymère ne ressemble pas àune substance humique unique, mais semble plutôt posséder des propriétés chimiques communes aux matériaux humiques de diverses sources.

Applications de l'acide maléique homopolymère :
Systèmes d'eau de refroidissement / traitement des eaux industrielles
Additif pour béton
Désalinisation de l'eau
Évaporation du pétrole brut

Utilisations de l'acide maléique homopolymère :
L'acide maléique homopolymère a une stabilité chimique et une résistance àla température élevées, et a un effet de limite de solubilité évident lorsque la valeur du pH est de 8,3.
L'acide maléique homopolymère peut chélater le plasma de calcium et de magnésium dans l'eau et possède une capacité de distorsion du réseau, ce qui peut améliorer la fluidité des boues.

L'acide maléique homopolymère est particulièrement adapté àl'inhibition du tartre dans les systèmes d'eau àhaute température tels que l'eau de chaudière.
L'acide maléique homopolymère peut être utilisé comme pipeline d'eau de champ pétrolifère, système d'eau de refroidissement en circulation et dessalement instantané de l'eau de mer et autres inhibiteurs de sédiments, inhibiteurs de tartre, etc., peut également être utilisé comme détergent industriel de base

L'acide maléique homopolymère est un inhibiteur de tartre efficace.
L'acide maléique homopolymère est principalement utilisé dans les chaudières àbasse pression, les systèmes de circulation d'eau de refroidissement industriels, les oléoducs, la déshydratation du pétrole brut et le dessalement instantané de l'eau de mer et d'autres aspects de l'inhibiteur de tartre, et peut être utilisé comme composant principal des agents de nettoyage avancés, mais peut également être utilisé comme agent de rinçage textile, réduit la teneur en cendres des textiles.

L'acide maléique homopolymère a toujours un bon effet d'inhibition et de dispersion du tartre sur le carbonate en dessous de 300 ℃, et le temps d'inhibition du tartre peut atteindre COOH.
En raison de l'excellente performance d'inhibition du tartre et de la résistance àhaute température de l'acide maléique homopolymère, l'acide maléique homopolymère est largement utilisé dans l'unité flash de dessalement d'eau de mer et dans la chaudière basse pression, la locomotive àvapeur, la déshydratation du pétrole brut, le pipeline de transfert d'eau et la circulation industrielle. eau de refroidissement.

De plus, l'acide maléique homopolymère a un certain effet d'inhibition de la corrosion, et l'effet du composé avec du sel de zinc est meilleur, ce qui peut empêcher efficacement la corrosion de l'acier au carbone.
L'acide maléique homopolymère est généralement (1 ~ 15) × 10-6 et un composé de phosphate organique, pour la circulation de l'eau de refroidissement, l'injection d'eau dans les champs pétrolifères, le traitement de déshydratation du pétrole brut et le traitement du four àchaudière basse pression, l'acide maléique homopolymère a un bon effet d'inhibition la formation de tartre et l'élimination du vieux tartre, et le taux d'inhibition du tartre peut atteindre 98 %.

L'acide maléique homopolymère a de meilleures performances lorsqu'il est combiné avec des phosphonates que lorsque les phosphonates sont utilisés seuls.
L'acide maléique homopolymère est compatible avec les composés d'ammonium quaternaire, bien qu'il ne soit pas affecté par le chlore ou d'autres biocides oxydants dans des conditions d'utilisation normales.

Le cacao àl'acide maléique homopolymère est utilisé pour l'inhibition du tartre de l'eau de refroidissement industrielle en circulation, des conduites d'eau des champs pétrolifères et de l'eau de chaudière.
Dessalement et prévention du tartre de l'eau de mer par évaporation flash.
Et utilisé comme ingrédient dans les agents de nettoyage avancés.

La posologie générale est de 1 à5 ppm.
L'acide maléique homopolymère peut être utilisé pour les canalisations d'eau des champs pétrolifères, les chaudières de locomotives àvapeur, les chaudières àmoyenne et basse pression, le dessalement de l'eau de mer, l'eau de refroidissement en circulation, l'inhibiteur de tartre et le dispersant.

L'acide maléique homopolymère peut également être utilisé comme agent de nettoyage textile.
Dosage général 2 × 10-6~10-5.

L'acide maléique homopolymère est utilisé comme inhibiteur de tartre et inhibiteur de corrosion dans les locomotives àvapeur, l'eau de chaudière industrielle, l'eau froide et le traitement par injection d'eau des champs pétrolifères.
L'acide maléique homopolymère est un inhibiteur de tartre àhaut rendement, principalement utilisé dans les chaudières àbasse pression, les systèmes de circulation d'eau de refroidissement industriels, les conduites d'eau des champs pétrolifères, la déshydratation du pétrole brut, etc.

L'acide maléique homopolymère a une stabilité chimique et une résistance àla température élevées, et a une valeur de pH évidente à8,3.
L'effet de limite de solubilité peut chélater avec le plasma de calcium et de magnésium dans l'eau et avoir une capacité de distorsion du réseau, ce qui peut améliorer la fluidité des boues.

L'acide maléique homopolymère est particulièrement adapté àl'inhibition du tartre des systèmes àeau chaude élevée tels que l'eau de chaudière.
L'acide maléique homopolymère peut être utilisé comme inhibiteur de sédiments, inhibiteur de tartre, etc. pour les conduites d'eau des champs pétrolifères, les systèmes d'eau de refroidissement en circulation et le dessalement de l'eau de mer par évaporation flash.
L'acide maléique homopolymère peut également être utilisé comme nettoyant industriel alcalin avec.

Propriétés de l'acide maléique homopolymère :
L'acide maléique homopolymère est un homopolymère d'acide maléique àbase de solvant, avec une inhibition de seuil évidente et une modification cristalline, et un poids moléculaire moyen d'environ 1000.
L'acide maléique homopolymère est l'inhibiteur de carbonate de calcium supérieur dans les conditions d'eau sévères de dureté élevée, d'alcalinité élevée et de température élevée et un agent de support de formulation multifonctionnel dans les systèmes d'eau industriels et d'autres applications connexes.

L'acide maléique homopolymère est largement utilisé dans les usines de dessalement des équipements de vaporisation flash, des chaudières basse pression, des locomotives àvapeur, de l'évaporation du pétrole brut, des oléoducs et des systèmes industriels d'eau froide àcirculation.

Nature de l'acide maléique homopolymère :
L'acide maléique homopolymère est un liquide transparent.
L'acide maléique homopolymère est soluble dans l'eau, stabilité chimique et stabilité thermique élevée, température de décomposition de 330.

50% de la solution aqueuse est un liquide visqueux jaune clair, la densité est supérieure ou égale à1.
2g/cm3, la valeur du pH est de 1 à2.
L'acide maléique homopolymère est un polyélectrolyte de faible poids moléculaire, non toxique, soluble dans l'eau, àhaute stabilité chimique et thermique, température de décomposition supérieure à330 ℃.

Méthode de préparation de l'acide maléique homopolymère :
La polymérisation a été initiée en présence de peroxyde de benzoyle avec de l'anhydride maléique comme matière première et du toluène comme solvant.

Méthode de synthèse de l'acide maléique homopolymère :
Ajouter une certaine quantité d'anhydride maléique et d'eau dans un ballon àquatre bouches de 1000 m équipé d'un thermomètre, d'un agitateur, d'un condenseur àreflux et d'un entonnoir àchute de pression constante, et augmenter la température à60 ℃.
Une fois l'anhydride maléique complètement dissous, ajoutez une quantité appropriée de catalyseur et d'AXL auxiliaire fabriqué par vous-même, démarrez l'agitateur et augmentez la température àla température définie en même temps, contrôlez une certaine température de réaction et ajoutez l'initiateur dans un certain délai. période de temps àtravers un entonnoir àchute de pression constante.
Après la chute, poursuivre la réaction de conservation de la chaleur pendant 2h pour obtenir des produits d'acide maléique homopolymère.

Méthode de production de l'acide maléique homopolymère :
200 parties d'anhydride maléique, 80 parties d'eau et une partie de catalyseur sont ajoutées dans la bouilloire.
Après chauffage et reflux, 100 parties de peroxyde d'hydrogène sont ajoutées goutte àgoutte à100 ~ 120 ℃.

Après la réaction, chauffer et reflux pendant 30 min pour obtenir un produit hydrolysé marron-jaune limpide et transparent.
Utilisation d'eau comme solvant et de tige d'acide maléique comme monomère en présence d'initiateur pour la polymérisation.
Voir tige d'acide maléique homopolymère hydrolysé pour plus de détails.

Manipulation et stockage de l'acide maléique homopolymère :

Précautions àprendre pour une manipulation sans danger:
Veiller àune bonne ventilation du poste de travail. Eviter le contact avec la peau et les yeux.
Porter un équipement de protection individuelle.

Mesures d'hygiène:
Ne pas manger, boire ou fumer lors de l'utilisation de l'acide maléique homopolymère.
Lavez-vous toujours les mains après avoir manipulé de l'acide maléique homopolymère.

Conditions d'un stockage sûr, y compris d'éventuelles incompatibilités:

Conditions de stockage:
Ne pas exposer àdes températures supérieures à50 °C/ 122 °F.
Protéger du soleil.

Conserver dans le contenant d'origine ou dans un contenant résistant àla corrosion et/ou doublé.
Stocker dans un récipient résistant àla corrosion avec une doublure intérieure résistante.

Conserver uniquement dans le contenant d'origine.
Conserver dans un endroit bien aéré.
Garder son calme.

Matériaux incompatibles :
Les métaux.

Durée de conservation de l'acide maléique homopolymère :
Dans des conditions de stockage appropriées, la durée de conservation est de 12 mois

Stabilité et réactivité de l'acide maléique homopolymère :

Réactivité:
L'acide maléique homopolymère est non réactif dans les conditions normales d'utilisation, de stockage et de transport.

Stabilité chimique:
Stable dans des conditions normales.

Possibilité de réactions dangereuses:
Aucune réaction dangereuse connue dans les conditions normales d'utilisation.

Condition àéviter :
Aucun dans les conditions de stockage et de manipulation recommandées.

Matériaux incompatibles :
Bases fortes.
Agent d'oxydation.
Peut être corrosif pour les métaux. les métaux.

Produits de décomposition dangereux:
Dans des conditions normales de stockage et d'utilisation, aucun produit de décomposition dangereux ne devrait apparaître.

Mesures de premiers secours de l'acide maléique homopolymère :

Après inhalation :
Emmenez la personne àl'air frais et gardez-la àl'aise pour respirer.

Après contact avec la peau :
Laver la peau àgrande eau.

Après contact visuel :
Rincer avec précaution àl'eau pendant plusieurs minutes.
Retirez les lentilles de contact, si elles sont présentes et faciles àfaire.
Continuez àrincer.

Si l'irritation oculaire persiste :
Obtenir des conseils/des soins médicaux.

Après ingestion :
Appeler un centre antipoison/médecin/médecin si vous ne vous sentez pas bien.

Principaux symptômes et effets (aigus et différés) :

Symptômes/effets après contact avec les yeux :
Irritation de l'oeil.

Soins médicaux immédiats et traitement spécial, si nécessaire :
Traiter de façon symptomatique.

Mesures de lutte contre l'incendie de l'acide maléique homopolymère :

Moyens d'extinction appropriés :
Pulvérisateur d'eau.
Poudre sèche.

Mousse.
Gaz carbonique.

Dangers spécifiques liés au produit chimique :

Réactivité:
L'acide maléique homopolymère est non réactif dans les conditions normales d'utilisation, de stockage et de transport.

Équipements de protection spéciaux et précautions pour les pompiers :

Protection pendant la lutte contre l'incendie :
N'essayez pas d'intervenir sans équipement de protection adapté.
Appareil respiratoire autonome.
Vêtement de protection complet.

Mesures àprendre en cas de rejet accidentel d'acide maléique homopolymère :

Précautions individuelles, équipement de protection et procédures d'urgence :

Procédures d'urgence:
Ventiler la zone de déversement.
Eviter le contact avec la peau et les yeux.

Équipement protecteur:
N'essayez pas d'intervenir sans équipement de protection adapté.

Précautions environnementales
Éviter le rejet dans l'environnement.

Méthodes et matériel de confinement et de nettoyage :

Méthodes de nettoyage :
Absorber le déversement de liquide dans un matériau absorbant.

Les autres informations:
Éliminer les matériaux ou les résidus solides dans un site autorisé.

Identifiants de l'acide maléique homopolymère :
N° CAS : 26099-09-2
Nom chimique : acide maléique homopolymère
Numéro CB : CB5491823
Formule moléculaire : C4H4O4
Poids moléculaire : 116,07
Numéro MDL : MFCD00284278

Formule : (C4H4O4)n
N° CAS : 26099-09-2
N° CE : n/a

N° CAS : [26099-09-2]
Code produit : FP45020
N° MDL : MFCD00284278
Formule chimique : (C4H4O4)n
Sourires : C(=C\C(=O)O)\C(=O)O
Densité : 1,23 g/cm3
Point d'éclair : 100 °C
Stockage : conserver entre 10 °C et 25 °C, bien refermer le récipient
Numéro ONU : UN3265
Groupe d'emballage : II
Classe : 8

CE / Numéro de liste : 607-861-7
N° CAS : 26099-09-2

Propriétés de l'acide maléique homopolymère :
Densité : 1,18 (48 % aqueuse)
Point d'éclair : 95 °C
température de stockage : 2-8°C

Formule moléculaire : C4H4O4;HOOCCH=CHCOOH;C4H4O4
Poids moléculaire : 116,07 g/mol
Nombre d'obligations rotatives : 2
Masse exacte : 116,010959 g/mol
Masse monoisotopique : 116,010959 g/mol
Nombre d'atomes lourds : 8
Complexité : 119
Nombre d'unités liées par covalence : 1
Couleur/Forme : Prismes monocliniques d'eau ; Cristaux blancs d'eau, d'alcool et de benzène ; Cristaux incolores
Odeur : Légère odeur acidulée
Point d'ébullition : 275 °F à760 mm Hg (se décompose) (NTP, 1992)

Formule moléculaire : C4H4O4
Masse molaire : 116,07
Densité : 1,18 (48 % aqueuse)
Point d'éclair : 95 °C
Conditions de stockage : 2-8°C

Spécifications de l'acide maléique homopolymère :
Aspect : liquide ambré
Contenu solide % : 48-52
pH (tel quel): 2.0 max
Densité (20℃, g/cm3): 1.16-1.22

Produits associés de l'acide maléique homopolymère :
2-Hydroxyisophtalate de diméthyle
2,6-diméthyl-4-hydroxypyridine
1-(1,1-Diméthyléthoxy)-N,N,N',N'-tétraméthyl-méthanediamine
(contient du tris(diméthylamino) méthane et du N,N-diméthylformamide di-tert-butyl acétal) (qualité technique)
(E)-6,6-diméthylhept-2-èn-4-yn-1-ol
Chlorothiophosphate de diméthyle

Noms de l'acide maléique homopolymère :

Noms des processus réglementaires :
Acide 2-butènedioïque (2Z)-, homopolymère

Noms IUPAC :
Acide (2R,3R)-2,3-diméthylbutanedioïque
Acide 2-butènedioïque (2Z)-, homopolymère
Acide 2‐butènedioïque (2Z)‐, homopolymère
ACIDE POLIMALEICO
Anhydride polymaléique hydrolysé
POLY(ACIDE MALÉIQUE)
Poly(acide maléique)
poly(acide maléique)
Acide polymaléique
Acide polymaléique
Acide polymaléique

Autres noms:
HPMA
Anhydride polymaléique hydrolysé
Anhydride polymaléique hydrolysé (HPMA)
PHOSPHITE MONOPOTASSIQUE

Autre identifiant :
26099-09-2

BUTYLOCTANOIC ACID, 2-butyloctanoic acid; Octanoic acid, 2-butyl-; Isocarb 12; N° CAS : 27610-92-0, Nom INCI : BUTYLOCTANOIC ACID, Nom chimique : 2-Butyloctanoic acid, N° EINECS/ELINCS : 248-570-1; Agent nettoyant : Aide àgarder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile).Tensioactif : Réduit la tension superficielle des cosmétiques et contribue àla répartition uniforme du produit lors de son utilisation. 248-570-1 [EINECS] 27610-92-0 [RN]; 2-Butyloctanoic acid ; 2-Butyloctansäure [German] ; Acide 2-butyloctanoïque [French] ;BUTYLOCTANOIC ACID ; Octanoic acid, 2-butyl- [ACD/Index Name]; 2-Butyloctanedioic acid ; 2-BUTYLOCTANOICACID; 2-Butyloctansaeure [German]; 2-Butyloctansaeure;4-02-00-01112 [Beilstein] 50905-10-7 [RN]; 53687-45-9 [RN]; 5-Undecanecarboxylic acid;PI-46872

Acide acrylique ; N° CAS : 79-10-7, Nom INCI : ACRYLIC ACID; N° EINECS/ELINCS : 201-177-9;2-PROPENOIC ACID; Acide acrylique. Noms anglais :ACROLEIC ACID; Acrylic acid; ETHYLENE CARBOXYLIC ACID; PROPENOIC ACID; VINYL FORMIC ACID; VINYLFORMIC ACID. Utilisation: Fabrication de produits organiques. fabrication de polymères Ses fonctions (INCI) : Agent d'entretien des ongles : Améliore les caractéristiques esthétiques des ongles. 2-Propenoic acid Acido acrilio; Acroleic acid; Acrylic acid;Acrylic acid, glacial; ACRYLIC ACID, STABILIZED; EU. ADN Dangerous Goods Lists, Directive 2008/68/EC, EU. ADR Dangerous Goods Lists, Directive 2008/68/EC, EU. RID Dangerous Goods Lists, Directive 2008/68/EC; acrylic acid; prop-2-enoic acid; EU. Worker Protection-Hazardous (98/24), EU. Workplace Signs, EU. Hazardous Waste Properties: Annex III (2008/98/EC), EU. Young People at Work (94/33); Ethylenecarboxylic acid; Glacial acrylic acid; Kyselina akrylova; Prop-2-enoic acid; Propene acid; Propenoic acid; Vinylformic acid; 2-propeno rūgštis (lt); 2-propensyra (sv); 2-propensyre (no); acid acrilic (ro); acid prop-2-enoic (ro); acide acrylique (fr); acido acrilico (it); acrylsyre (da); Acrylsäure (de); acrylzuur (nl); akrilna kiselina (hr); akrilna kislina (sl); akrilo rūgštis (lt); akrilsav (hu); akrilskābe (lv); akrylová kyselina (cs); akrylsyra (sv); akrylsyre (no); Akryylihappo (fi); Akrüülhape (et); kwas akrylowy (pl); kwas etenokarboksylowy (pl); kwas propenowy (pl); kyselina akrylová (sk); kyselina propénová (sk); Prop-2-eenhape (et); Prop-2-eenihappo (fi); prop-2-enojska kislina (sl); prop-2-enonska kiselina (hr); prop-2-enová kyselina (cs); prop-2-énsav (hu); Propensäure (de); propēn-2 skābe (lv); ácido 2-propenoico (es); ácido 2-propenóico (pt); ácido acrílico (es); ακρυλικο οξύ (el); акрилова киселина (bg); проп-2-енова киселина (bg) 2-hydroxyethyl methacrylate; Acrylic Acid (stabilized with MEHQ); Acrylic acid ; acrylic acid, acrylic acid glacial, acrylic acid technical; acrylicacid; prop-2-enoate

N° CAS : 124-04-9 ; EC / List no.: 204-673-3; Mol. formula: C6H10O4; 1,4-Butanedicarboxylic acid; 1,6-Hexanedioic acid; Acifloctin; Acinetten; Adilactetten; Adipate;Adipic acid; Adipinic acid; Adipinsaure; Kyselina adipova; Molten adipic acid; acid adipic (ro); acide adipique (fr); acido adipico (it); Adipiinhape (et); Adipiinihappo (fi); adipinezuur (nl); adipinsav (hu); adipinska kiselina (hr); adipinska kislina (sl); adipinsyra (sv); adipinsyre (da); Adipinsäure (de); adipo rūgštis (lt); adipová kyselina (cs); adipīnskābe (lv); hexandikarboxylsyra (sv); kwas adypinowy (pl); kwas butano-1,4-dikarboksylowy (pl); kyselina adipová (sk); ácido adípico (es); αδιπικό οξύ (el); адипинова киселина (bg) Hexanedioic acid; : 1, 4-butanedicarboxylic acid; 1,4-buthanediacetic acid; Adipic acid ,CAS N°124-04-9; Hexamethylenediamine-adipate; hexan-1,6-dioic acid; hexane-1,6-dioic acid; Hexanedioic acid / Adipic acid; Adipic acid (8CI); adipin saure; ADIPINSAEURE L'acide adipique ou acide 1,6-hexanedioïque est un diacide carboxylique aliphatique. Il est utilisé principalement pour la fabrication du nylon, et plus généralement pour la synthèse des polyamides. C'est également un additif alimentaire (E355) utilisé pour acidifier des boissons non alcoolisées ou contrôler l’acidité des cosmétiques. Il contribue aussi au goût acide des betteraves. De formule CO2H(CH2)4CO2H, il se présente sous forme d'un solide cristallisé blanc. Il possède un groupe acide àses 2 extrémités, comme l’acide téréphtalique, avec possibilité de développer des chaînes àchacune de ses extrémités. Par estérification avec un alcool double, tel l’éthylène glycol, il formera un polyester. Il peut également donner un polyamide.

Nom inci: Aminoethylphosphinic acid. Nom français: Acide aminoethylphosphinique. Aminoethylphosphinic acid | 1-aminoethylphosphinique acid. 1-aminoethylphosphinic acid; Phosphinic acid, P-(1-aminoethyl)-; (1-azaniumylethyl)phosphinate; N° CAS. : 74333-44-1, Nom INCI : AMINOETHYLPHOSPHINIC ACID, Nom chimique : Phosphinic acid, (1-aminoethyl)-, Ses fonctions (INCI) : Agent d'entretien de la peau : Maintient la peau en bon état. (1-Aminoethyl)phosphinic acid ; (1-Aminoethyl)phosphinsäure [German] ; 74333-44-1 [RN] Acide (1-aminoéthyl)phosphinique [French] ; Aminoethylphosphinic acid; Phosphinic acid, (1-aminoethyl)-, (-)-; Phosphinic acid, P-(1-aminoethyl)- (1-Amino-ethyl)-phosphinic acid; 1-aminoethylphosphinic acid; 71937-28-5 [RN]; AMINOETHYLPHOSPHINICACID; PHOSPHINIC ACID, (1-AMINOETHYL)-, (S)-

ASCORBIC ACID, N° CAS : 50-81-7 / 62624-30-0 - Acide ascorbique (Vitamine C),utres langues : Acido ascorbico, Askorbinsäure, Ácido ascórbico, Nom INCI : ASCORBIC ACID; Nom chimique : Ascorbic acid, N° EINECS/ELINCS : 200-066-2 / 263-644-3. Additif alimentaire : E300, Plus connu sous le nom de Vitamine C, l'acide ascorbique est utilisé en cosmétique pour ses propriétés antioxydantes. On le retrouve assez régulièrement dans les actifs anti-âge, puisque qu'il protège les cellules des dégâts causés par les radicaux libres et unifie le teint. Il est aussi présent dans de nombreux autres produits de soin pour ces propriétés. Il est présent sous forme naturel dans les fruits et légumes (citrons, oranges, kiwis ...)Ses fonctions (INCI): Antioxydant : Inhibe les réactions favorisées par l'oxygène, évitant ainsi l'oxydation et la rancidité. Régulateur de pH : Stabilise le pH des cosmétiques. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Agent d'entretien de la peau : Maintient la peau en bon état. Noms français :3-KETO-L-GULFURANOLACTONE; 3-OXO-L-GULOFURANOLACTONE; Acide ascorbique; L(+)-ASCORBIC ACID; L-3-KETOTHREOHEXURONIC ACID LACTONE; L-ASCORBIC ACID; L-LYXOASCORBIC ACID; L-TREO-HEX-ENONIC ACID, GAMMA-LACTONE; L-XYLOASCORBIC ACID; VITAMINE C XYLOASCORBIC ACID, L-. Noms anglais : Ascorbic acid; VITAMIN C. Utilisation: Vitamine. Ascorbic acid ; Vitamin C ; (5R)-5-[(1S)-1,2-Dihydroxyethyl]-3,4-dihydroxy-2(5H)-furanon [German]; (5R)-5-[(1S)-1,2-Dihydroxyethyl]-3,4-dihydroxy-2(5H)-furanone; (5R)-5-[(1S)-1,2-Dihydroxyéthyl]-3,4-dihydroxy-2(5H)-furanone; (5R)-5-[(1S)-1,2-Dihydroxyethyl]-3,4-dihydroxyfuran-2(5H)-one; 200-066-2 [EINECS]; acide ascorbique [French]; acido ascorbico [Spanish]; ácido ascórbico [Spanish]; acidum ascorbicum [Latin]; Ascorbinsäure [German]; Calscorbate; Cetebe; L-AA; L-Ascorbic acid; L-Threoascorbic acid; monodehydro-L-ascorbic acid; аскорбиновая кислота [Russian]; حمض أسكوربيك [Arabic]; 抗坏血酸 [Chinese]; (+)-ascorbate; (+)-Ascorbic acid; (2R)-2-[(1S)-1,2-dihydroxyethyl]-3,4-dihydroxy-2H-furan-5-one; (5R)-5-[(1S)-1,2-dihydroxyethyl]-3,4-dihydroxy-2,5-dihydrofuran-2-one (R)-5-((S)-1,2-dihydroxyethyl)-3,4-dihydroxyfuran-2(5H)-one; [(2R)-2-(1,2-dihydroxyethyl)-4-hydroxy-5-oxo-2,5-dihydrofuran-3-yl]oxidanyl; 16351-10-3 [RN]; 2-(1,2-Dihydroxyethyl)-4,5-dihydroxyfuran-3-one; 299-36-5 [RN]; 3-Keto-L-gulofuranolactone; 3-Oxo-L-gulofuranolactone; 3-Oxo-L-gulofuranolactone (enol form); 5-(1,2-Dihydroxy-ethyl)-3,4-dihydroxy-5H-furan-2-one; acidum ascorbinicum; Adenex; AHI; Allercorb; Antiscorbic vitamin; Arco-cee; ASC; Ascoltin; Ascorb; Ascor-B.I.D.; Ascorbajen; Ascorbic Acid DC97SF; ascorbicab; Ascorbicap; Ascorbicin Ascorbin; Ascorbutina; Ascorin; Ascorteal; Ascorvit; ascrobin; Cantan; Cantaxin; Catavin C; ce lent; Cebicure; Cebid []; Cebion; Cebione; Cee-caps TD; Cee-vite; Cegiolan; Ceglion Celaskon; Cell C; Cemagyl; Ce-Mi-Lin; Cemill; Cenetone; Cenolate; Cereon; Cergona; Cescorbat; Cetamid; cetane; Cetane-Caps TC; Cetane-caps TD; Cetemican; Cevalin; Cevatine; Cevex; Cevi-bid; CeviminCE-VI-Sol; Cevital; Cevitamate; Cevitamic acid; Cevitamin; Cevitan; Cevitex; Cewin; Chewcee; Ciamin; Cipca; Citriscorb; Citrovit; C-Level; C-Long; Colascor; Concemin; C-Quin; C-Span; C-Vimin; Davitamon C; D-Isoascorbic acid; Dora-C-500; Duoscorb; E300; E-300; Hicee; Hybrin; IDO-C; Juvamine; Kangbingfeng; l-​(+)​-​ascorbic acid; L(+)-ascorbate; L-(+)-ascorbate; L-(+)-ascorbic acid; l(+)-ascorbic acid standard; l,3-ketothreohexuronic acid; Laroscorbine; L-ascorbate; L-Ascorbate;Vitamin C; L-ASCORBIC ACID 2-(DIHYDROGEN PHOSPHATE) CALCIUM SALT (2:3); l-ascorbic acid (vitamin c); L-Ascorbic acid ACS reagent grade; L-ASCORBIC ACID-6,6-Dl-ascorbic acid-用于细胞培养; Lemascorb; Liqui-Cee; L-lyxoascorbate; L-Lyxoascorbic acid; L-threo-Ascorbic acid; L-threo-hex-2-enono-1,4-lactone; L-xyloascorbate; L-XYLOASCORBIC ACID; meilun; Meri-C; Natrascorb; Natrascorb injectable; Planavit C; Proscorbin; Redoxon []; Ronotec 100; Rontex 100; Roscorbic; Rovimix C; Scorbacid; Scorbu C; Scorbu-C; Secorbate; Semidehydroascorbate; Semidehydroascorbic acid; Suncoat VC 40; Testascorbic; Vasc; Vicelat; Vicin; Vicomin C; Viforcit; Viscorin; Vitace; Vitacee; Vitacimin; Vitacin; Vitamisin; Vitascorbol; Xitix; γ-lactone L-threo-Hex-2-enonate; γ-lactone L-threo-Hex-2-enonic acid

Acide aspartique (dl-); Acide DL-aspartique. Noms anglais :Aspartic acid, DL-; dl-Aspartic acid. Utilisation: Produit organique; ASPARTIC ACID, N° CAS : 56-84-8 / 617-45-8 - Acide aspartique, Nom INCI : ASPARTIC ACID, Nom chimique : Aspartic acid, N° EINECS/ELINCS : 200-291-6 / 210-513-3.Nom UICPA acide (2S)-2-aminobutanedioïque; Synonymes : D, Aspacide 2-aminosuccinique L’acide aspartique (abréviations IUPAC-IUBMB : Asp et D), est un acide α-aminé dont l'énantiomère L est l'un des 22 acides aminés protéinogènes, encodé sur les ARN messagers par les codons GAU et GAC. Il est caractérisé par la présence d'un groupe carboxyle –COOH àl'extrémité de sa chaîne latérale, lui conférant un point isoélectrique de 2,77, ce qui en fait le résidu le plus acide dans les protéines. Ses fonctions (INCI): Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Conditionneur capillaire : Laisse les cheveux faciles àcoiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Agent d'entretien de la peau : Maintient la peau en bon éta.Acid D,L-aspart; Aspartic acid; 2-Aminobutanedioic acid DL-Aspartic acid (±)-2-Aminosuccinic acid (±)-2-Aminosuccinic acid (R,S)-Aspartic acid 200-291-6 [EINECS] 2-Aminobutandisäure [German] 2-Aminosuccinic acid 617-45-8 [RN] 774618 [Beilstein] acide 2-aminobutanedioïque [French] Acide 2-aminosuccinique [French] Acide aspartique [French] Aminosuccinic acid ASP Asparaginic acid Asparaginsäure [German] Aspartic acid Aspartic acid, D- ASPARTIC ACID, DL- DL-2-Aminobutanedioic acid DL-Aminosuccinic acid DL-Asparagic acid H-DL-Asp-OH α-Aminosuccinic acid (±)-Aspartic Acid (±)-Aspartic Acid 1-deoxy-1-(N6-lysino)-D-fructose 217-234-6 [EINECS] 2-Amino Maleic Acid 2-aminobutanedioic acid 2-azaniumyl-4-hydroxy-4-oxobutanoate 874742-68-4 secondary RN [RN] DL-Asp-OH DL-Asp-OH|2-Aminosuccinic acid H-Asp-OH MFCD00063081 [MDL number] N-acetyl-seryl-aspartate

AZELAIC ACID, N° CAS : 123-99-9 - Acide azélaïque, Nom INCI : AZELAIC ACID, Nom chimique : Nonanedioic acid, N° EINECS/ELINCS : 204-669-1, Régulateur de pH : Stabilise le pH des cosmétiques. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Noms français :1,7-HEPTANEDICARBOXYLIC ACID; ACIDE AZELAIQUE; ACIDE; HEPTANEDICARBOXYLIQUE-1,7; ACIDE NONANEDIOIQUE; HEPTANEDICARBOXYLIC ACID; NONANEDIOIC ACID. Noms anglais : ANCHOIC ACID; AZELAIC ACID;LEPARGYLIC ACID Utilisation: Fabrication de produits organiques et de résines. 1,7-Heptanedicarboxylic acid; 123-99-9 [RN]; 204-669-1 [EINECS]; Acide azélaïque [French] ; acide nonanedioïque [French]; Acido azelaico [Spanish]; anchoic acid; Azalaic Acid; Azelaate [; Azelaic acid ; Azelainic acid; Azelainsäure [German] ; Azelex ; Finaceae; lepargylic acid; Nonandisäure [German]; Nonanedioic acid Skinoren ; 1,7-dicarboxyheptane; 1,9-NONANEDIOIC ACID; acide azelaique [French]; Acido azelaico [Spanish]; Acidum acelaicum Acidum azelaicum [Latin] AHI AZ1 azelaicacid Azelainsäure Azelate Emery's L-110 Finacea Heptanedicarboxylic acid n-nonanedioic acid Nonandisäure Nonanedioate Nonanedionic acid Skinorem Zumilin

Acide benzènesulfonique, dérivés mono-alkyles en C10-14; Noms anglais :Benzenesulfonic acid, mono-C10-14-alkyl derivativesC10-14 ALKYL BENZENESULFONIC ACID, N° CAS : 85117-49-3, Nom INCI : C10-14 ALKYL BENZENESULFONIC ACID, N° EINECS/ELINCS : 285-599-9. Agent nettoyant : Aide àgarder une surface propre. Agent moussant : Capture des petites bulles d'air ou d'autres gaz dans un petit volume de liquide en modifiant la tension superficielle du liquide. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue àla répartition uniforme du produit lors de son utilisation. Benzenesulfonic acid, mono-C10-14-alkyl derivs;

BENZOIC ACID, N° CAS : 65-85-0 - Acide benzoïque. Autres langues : Acido benzoico, Benzoesäure, Ácido benzoico. Nom INCI : BENZOIC ACID. Nom chimique : Benzoic acid; N° EINECS/ELINCS : 200-618-2.Principaux synonymes. Noms français : Acide benzoique; Acide benzoïque;Benzenecarboxylic acid; Benzeneformic acid; Benzenmethanoic acid; Carboxybenzene Phenyl carboxylic acid; Phenyl formic acid; Phenylcarboxylic acid; Phenylformic acid. Noms anglais : Benzoic acid; Dracylic acid. L'acide benzoïque, de formule chimique C6H5COOH (ou C7H6O2) est un acide carboxylique aromatique dérivé du benzène.Il est utilisé comme conservateur alimentaire et est naturellement présent dans certaines plantes. C'est par exemple l'un des principaux constituants de la gomme benjoin, utilisée dans des encens dans les églises de Russie et d'autres communautés orthodoxes. Bien qu'étant un acide faible, l'acide benzoïque n'est que peu soluble dans l'eau du fait de la présence du cycle benzénique apolaire. On trouve de l'acide benzoïque dans les plantes alimentaires : - en quantité notable dans le canneberge d'Amérique11 (Vaccinium macrocarpon) : 48,10 mg·100ml-1. - dans une moindre mesure dans la poudre de cacao (Theobroma cacao) : 0,06 mg·100ml-1. Parmi les principaux composés qui dérivent de l'acide benzoïque, on peut citer l'acide salicylique et l'acide acétylsalicylique plus connu sous le nom d'aspirine. En tant qu'additif alimentaire, il est référencé en Europe sous le code E210. Ses sels, que l'on appelle des benzoates, sont référencés sous les numéros : E211 Benzoate de sodium (Ba) E212 Benzoate de potassium (Ba) E213 Benzoate de calcium (Ba) Au-dessus de 370 °C, il se décompose en formant du benzène et du dioxyde de carbone. L'acide benzoïque a une odeur forte et est facilement inflammable. Utilisation: Agent de préservation alimentaire, fabrication de produits organiques Additif alimentaire : E210. L'acide benzoïque est utilisé en tant que conservateur dans les cosmétiques. Agent de foisonnement : Réduit la densité apparente des cosmétiques. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Conservateur : Inhibe le développement des micro-organismes dans les produits cosmétiques.Acid benzoic (ro) Acide benzoïque (fr) Acido benzoico (it) Aċidu benżojku (mt) Bensoehape (et) Bensoesyra (sv) Bentsoehappo (fi) Benzenkarboksirūgštis (lt) Benzoe-säure (de) Benzoesav (hu) Benzoesyre (da) Benzoic acid (no) Benzojeva kiselina (hr) Benzojska kislina (sl) Benzoová kyselina (cs) Benzoskābe (lv) benzosyre (no) Benzoëzuur (nl) Kwas benzoesowy (pl) Kyselina benzoová (sk) Ácido benzoico (es) Βενζοϊκό οξύ (el) Бензоена киселина (bg) benzene carboxylic acid Benzenecarboxylic acid Benzoesäure Benzoic Acid Phenylformic acid, Benzene carboxylic acid Acide benzoique [French] Acide benzoïque [French] Acido benzoico [Italian] Acidum benzoicum [Latin] Alcohol bencílico [Spanish] Benzenecarboxylic acid benzeneformic acid Benzenemethanoic acid Benzoesaeure [German] Benzoesäure [German] Benzoic acid [ACD/Index Name] [USP] [Wiki] 苯甲酸 [Chinese] Acidum benzoicum benzenemethonic acid Benzoic acid 100 µg/mL in Acetone Benzoic acid, ACS reagent Carboxybenzene DB03793 Diacylic acid Dracylic acid Euxyl K 100 Oracylic acid Phenolcarbinol Phenylcarboxy PHENYLCARBOXYLIC ACID Phenylformic acid Retarder BAX Retardex Tenn-Plas UCEPHAN Unisept BZA

BORIC ACID, N° CAS : 10043-35-3 / 11113-50-1 - Acide borique, Nom INCI : BORIC ACID, Nom chimique : Boric acid, N° EINECS/ELINCS : 233-139-2 / 234-343-4, acide borique borate d'hydrogène. ACIDE BORACIQUE; Acide borique; ACIDE ORTHOBORIQUE; BORON TRIHYDROXIDE; O-BORIC ACID; TRIHYDROXYDE DE BORE. Noms anglais :BORA ; BORACIC ACID; Borate compounds, Inorganic [10043-35-3], boric acid; Boric acid; HYDROGEN BORATE; ORTHOBORIC ACID. Utilisation: Agent ignifuge, fabrication de produits pharmaceutiques. BoratesSynonymes : acide boracique; acide orthoborique. Additif alimentaire : E284,Antimicrobien : Aide àralentir la croissance de micro-organismes sur la peau et s'oppose au développement des microbes. Régulateur de pH : Stabilise le pH des cosmétiques. Dénaturant : Rend les cosmétiques désagréables. Principalement ajouté aux cosmétiques contenant de l'alcool éthylique.Ce solide blanc, parfois légèrement coloré, cristallise dans un réseau triclinique. Il se présente sous forme d'un solide cristallisé en paillettes nacrées. Assez peu soluble dans l'eau, c'est un acide faible àtrès faible. Il est souvent employé comme antiseptique bien que toxique, insecticide, absorbeur de neutrons dans les centrales nucléaires pour contrôler le taux de fission de l'uranium, et comme précurseur d'autres composés chimiques. Cet acide de Lewis tire son nom de l'un de ses composants, le bore, sa formule brute est H3BO3 ou en respectant mieux la structure àliaisons covalentes B(OH)3. L'acide borique moléculaire peut provenir de la simple décomposition du minéral naturel nommée sassolite qui, décrit par sa formule B(OH)3, n'est qu'un assemblage de plans d'acide borique stabilisés par des liaisons hydrogènes7. Il existe sous forme de cristaux incolores ou de poudre blanche se dissolvant dans l'eau. L'acide libre est présent sous forme native ou régénérée dans certaines zones possédant des batholithes granitiques proches de la surface telles que la Toscane, les îles Lipari et au Nevada, ses effluents sont mélangés àla vapeur issue des fissures de la croûte terrestre. En Toscane, on récupère l'acide borique dans des jets de vapeur d'eau surchauffée (100 à215 °C) d'origine volcanique, exploités comme source d'énergie ; la vapeur, hydrolysant des borates dans les profondeurs du sol de cette région, contient en effet de l'acide borique et divers sels minéraux. Celle qui s'échappe librement des fissures du sol (soffioni) est simplement condensée dans des bassins (lagoni). La présence de l'acide borique ou de ses sels a été décelée dans l’eau de mer, et existerait également dans les végétaux et plus particulièrement dans presque tous les fruits8 où il pourrait jouer un certain rôle d'insecticide naturel. Disposition spatiale de molécules (hélicoïdales) d'acide borique dans son cristal artificiel ou dans la sassolite naturelle L'acide borique est le produit de dégradation ultime (souvent àl'aide d'un acide fort) de nombreux borates : borax, boracite, boronatrocalcite, colemanite, borocalcite, ascharite, kaliborite, kernite, kurnakovite, pinnaïte, pandermite, tunellite, larderellite, probertite, inderite, hydroboracite, etc., mais aussi howlite et bakérite, en plus des minéraux qui peuvent contenir l'acide borique en partie comme la harkérite ou la sassolite.L'acide borique est produit principalement àpartir de minerai de borate par sa réaction avec l’acide sulfurique. La plus grande source de borates dans le monde est une mine àciel ouvert située àBoron.En agriculture L'acide borique et ses sels sont utilisés comme fertilisants en agriculture conventionnelle et biologique14. La carence en bore est la carence en oligoéléments la plus répandue dans le monde et occasionne des pertes de rendement importantes chez les plantes cultivées et les arbres fruitiers15. En médecine et biologie Antiseptique Il peut être utilisé comme antiseptique pour les brûlures ou les coupures et est parfois employé dans les pommades et les onguents ou est utilisé dans une solution très diluée comme bain oculaire (eau boriquée). Comme composé anti-bactérien, l'acide borique peut également être prescrit comme traitement de l’acné. On l'utilise encore comme antiseptique pour l'oreille en plongée scaphandre, àraison d'une goutte d'alcool boriqué à2 % par oreille.[réf. nécessaire] Le borate de sodium, un antiseptique doux, associé àd’autres composants appropriés peut également être proposé en usage externe pour des maladies des yeux, telle que la sécheresse oculaire. Antimycosique L'acide borique peut être utilisé pour traiter les levures et les mycoses comme les candidoses (mycoses vaginales) en remplissant de poudre d'acide borique des ovules qui seront insérés dans la cavité vaginale au coucher pendant trois àquatre nuits consécutives. en solution il peut être prescrit pour traiter certaines formes d’otites externes (infection de l'oreille) chez l’homme ou l’animal. Le conservateur dans les flacons d'urine (bouchon rouge) au Royaume-Uni est de l’acide borique. Il est également employé en prévention du pied d'athlète, en insérant la poudre dans les chaussettes ou les bas. Solution tampon Le borate de lithium est le sel de lithium de l'acide borique employé en laboratoire comme solution tampon pour le gel couramment employé dans les tampons d'électrophorèse des acides nucléiques (tels que les tampons TBE, SB et LB). Il peut être utilisé pour l’électrophorèse de l'ADN et de l'ARN, en gel de polyacrylamide et en gel d'agarose. Insecticide L'acide borique est également souvent utilisé comme insecticide relativement peu toxique, pour l’extermination des cancrelats, termites, fourmis, puces, et beaucoup d'autres insectes. Il peut être employé directement sous la forme de poudre pour les puces et les cancrelats, ou être mélangé avec du sucre ou de la gelée pour les fourmis. C'est également un composant de beaucoup d’insecticides du commerce. Dans cette utilisation, particulièrement dans le cas des cancrelats, l'acide borique sous forme de poudre est appliqué dans les zones fréquentées par les insectes. Les fines particules s'accrochent aux pattes des insectes et causent par la suite des brûlures chimiques mortelles. L'acide borique est commercialisé pour cet usage dans des quartiers résidentiels dans des zones urbaines infestées par les cancrelats. Esters of boric acid Octaborates Salts of boric acid Trioctyldodecyl borate Translated names Acid boric (ro) Acide borique (fr) Acido borico (it) Aċidu boriku (mt) Boorhape (et) Boorihappo (fi) Boorzuur (nl) Boric acid (no) Borna kiselina (hr) Boro rūgštis (lt) Borova kislina (sl) Borskābe (lv) Borsyra (sv) Borsyre (da) Borsäure (de) Bórsav (hu) Kwas borowy (pl) Kyselina boritá (cs) Kyselina trihydrogenboritá (sk) Ácido bórico (es) Βορικό οξύ (el) Борна киселина (bg) Acidium boricum Boric acid (H3BO3) boric acid. Trihydroxidoboron Boric acidTrihydrooxidoboron boric acidTrihydroxidoboron Ortho-boric Acid Orthoboric Acid TRHIOSSOBORIC ACID Trihydroxidoboron s BORIC ACID 99,9% Optibor Optibor HG Optibor TG Optibor TP 10043-35-3 [RN] Acide borique [French] acidum boricum [Latin] B(OH)3 [Formula] Boric acid Boric acid-11B Borsäure [German] Orthoboric acid (10B)Orthoboric acid 7440-42-8 [RN] Acidum boricum Ant flip Boracic acid Boracic Acid, Orthoboric Acid Borate (H3bo3) borate ion Boric acid ACS grade Boric acid Electrophoresis grade Boric acid flakes Boric acid, biochemical grade Boric Acid, Granular Boric acid, NF/USP grade Boric Acid, Powder Boric acid-d3 BORIC-11B ACID Borofax Boron hydroxide Boron trihydroxide Borsaeure Borsaure H3-BO3 Heptaoxotetra-Borate(2-) Homberg's salt Hydrogen borate hydrogen orthoborate InChI=1S/BH3O3/c2-1(3)4/h2-4H Kill-off Kjel-sorb Orthboric acid Orthoboricacid Orthoborsaeure tetraborate trihydridoborate trihydroxidoboron Trihydroxyborane Trihydroxyborone WLN: QBQQ

CAPRIC ACID, N° CAS : 334-48-5, Nom INCI : CAPRIC ACID, Nom chimique : Decanoic acid, N° EINECS/ELINCS : 206-376-4, Agent nettoyant : Aide àgarder une surface propre; Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile), Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit, Tensioactif : Réduit la tension superficielle des cosmétiques et contribue àla répartition uniforme du produit lors de son utilisation, Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques; Noms français : 1-NONANECARBOXYLIC ACID; Acide caprique; ACIDE CAPRIQUE NORMAL; ACIDE DECANOIQUE; ACIDE DECANOIQUE NORMAL;DECOIC ACID; DECYCLIC ACID; DECYLIC ACID; N-CAPRIC ACID; N-DECANOIC ACID; N-DECYLIC ACID. Noms anglais : Capric acid; CAPRINIC ACID; CAPRYNIC ACID; DECANOIC ACID; N-DECOIC ACID; Utilisation: Fabrication de produits organiques, additif alimentaire. Capric Acid; Capric acid (CAS 334-48-5); n-decanoic acid Translated names Acid decanoic (ro) Acide décanoïque (fr) Acido decanoico (it) Aċidu dekanojku (mt) Decaan-zuur (nl) Decanoic acid (no) Decansyre (da) Decansäure (de) Dekaanhape (et) Dekaanihappo (fi) Dekano rūgštis (lt) Dekanojska kislina (sl) Dekanová kyselina (cs) Dekanska kiselina (hr) Dekansyra (sv) Dekánsav (hu) Dekānskābe (lv) Kwas dekanowy (pl) Kyselina dekánová (sk) Ácido decanoico (es) Δεκανικό οξύ (el) Деканова киселина (bg) 1- Decansäure 2-Ethyl-7-sulfo-decansäure Deacnoic acid s Capric Acid – Palmata 1099 Ecoric 10/95 Ecoric 10/99 KORTACID (KORTACID 1099/ 1098/1095/1090) Kortacid 1098 MASCID 1098 Palmac 98-10 Palmac 99-10 Palmac 99-10/MB RADIACID 0610 RADIACID 0613 RADIACID 0691

CITRIC ACID, N° CAS : 77-92-9 / 5949-29-1 - Acide citrique, Origine(s) : Naturelle, Synthétique, Autres langues : Acido citrico, Zitronensäure, Ácido cítrico, Nom INCI : CITRIC ACID, Nom chimique : 2-Hydroxy-1,2,3-propanetricarboxylic acid, N° EINECS/ELINCS : 201-069-1, Additif alimentaire : E330. L'acide citrique est un des principaux actifs du citron. Il est souvent utilisé pour équilibrer le pH (trop basique) des produits cosmétiques. Il est aussi présent dans certains produits de bain (bombes de bain, galets de bain ou "poudres magiques") en raison de ses propriétés effervescentes.Ses fonctions (INCI). Régulateur de pH : Stabilise le pH des cosmétiques. Agent de chélation : Réagit et forme des complexes avec des ions métalliques qui pourraient affecter la stabilité et / ou l'apparence des produits cosmétiques. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit

DEHYDROACETIC ACID, N° CAS : 520-45-6 / 771-03-9 / 16807-48-0 - Acide déhydroacétique, Autres langues : Acido deidroacetico, Dehydroessigsäure, Ácido deshidroacético. Nom INCI : DEHYDROACETIC ACID, Nom chimique : 3-Acetyl-6-methyl-2H-pyran-2,4(3H)-dione, N° EINECS/ELINCS : 208-293-9 / 212-227-4 / - Additif alimentaire : E265. Classification : Règlementé, Conservateur. L'acide déhydroacétique est utilisé dans les cosmétiques en tant que conservateur pour ses actions de fongicide et bactéricide. Il est employé sous la dénomination E265 en alimentaire. Comme il est Biodégradable, ce produit chimique ne pose pas de problème pour l'environnement, et les risques pour la santé restent assez faible. Notez toutefois, que le composé est interdit dans les sprays de type aérosol. L'acide déhydroacétique est autorisé en Bio.Ses fonctions (INCI): Conservateur : Inhibe le développement des micro-organismes dans les produits cosmétiques.Noms français : 3-ACETYL-4-HYDROXY-6-METHYL-2H-PYRAN-2-ONE 3-ACETYL-6-METHYL-2,4-PYRANDIONE 3-ACETYL-6-METHYLDIHYDROPYRANDIONE-2,4 3-ACETYL-6-METHYLPYRANDIONE-2,4 4-HEXENOIC ACID, 2-ACETYL-5-HYDROXY-3-OXO-, DELTA-LACTONE ACETYL-3 METHYL-6 PYRANDIONE-2,4 Acide déhydroacétique METHYLACETOPYRONONE Noms anglais : Dehydroacetic acid Utilisation: Fabrication de produits organiques, bactéricide

THIODIPROPIONIC ACID N° CAS : 111-17-1 - Acide thiodipropanoïque Nom INCI : THIODIPROPIONIC ACID Nom chimique : 3,3'-Thiodipropionic Acid N° EINECS/ELINCS : 203-841-3 Additif alimentaire : E388 Ses fonctions (INCI) Agent d'entretien de la peau : Maintient la peau en bon état

SACCHAROSONIC ACID; ISOASCORBIC ACID; ERYTHORBIC ACID; N° CAS : 89-65-6 - Acide érythorbique. Nom INCI : ERYTHORBIC ACID. Nom chimique : 2,3-Didehydro-D-erythro-hexono-1,4-lactone; D-erythro-hex-2-enonic acid, gamma-lactone. N° EINECS/ELINCS : 201-928-0. Additif alimentaire : E315. Ses fonctions (INCI). Antioxydant : Inhibe les réactions favorisées par l'oxygène, évitant ainsi l'oxydation et la rancidité. Noms français : ACIDE ARABOASCORBIQUE ACIDE D-ERYTHORBIQUE ACIDE D-ISOASCORBIQUE ACIDE ERYTHORBIQUE ACIDE GLUCOSACCHARONIQUE ACIDE ISOASCORBIQUE ACIDE SACCHAROSONIQUE D-ERYTHRO-3-KETOHEXONIC ACID LACTONE D-ERYTHRO-3-OXOHEXONIC ACID LACTONE D-ERYTHRO-ASCORBIC ACID D-ERYTHRO-HEX-2-ENONIC ACID GAMMA-LACTONE D-ERYTHRO-HEX-2-ENONIC ACID, GAMMA-LACTONE Noms anglais : ARABOASCORBIC ACID D-ARABOASCORBIC ACID D-ERYTHORBIC ACID D-ISOASCORBIC ACID ERYTHORBIC ACID GLUCOSACCHARONIC ACID ISOASCORBIC ACID SACCHAROSONIC ACID Utilisation et sources d'émission Agent anti-oxydant, agent de préservation alimentaire. (5R)-5-[(1R)-1,2-Dihydroxyethyl]-3,4-dihydroxy-2(5H)-furanon [German] (5R)-5-[(1R)-1,2-Dihydroxyethyl]-3,4-dihydroxy-2(5H)-furanone (5R)-5-[(1R)-1,2-Dihydroxyéthyl]-3,4-dihydroxy-2(5H)-furanone [French] (5R)-5-[(1R)-1,2-Dihydroxyethyl]-3,4-dihydroxyfuran-2(5H)-one 228-973-9 [EINECS] 2410 311332OII1 84271 [Beilstein] 89-65-6 [RN] D-(-)-Isoascorbic acid D-Araboascorbic Acid D-erythro-3-Ketohexonic acid lactone D-erythro-3-Oxohexonic acid lactone D-erythro-Hex-2-enoic acid γ-lactone D-erythro-Hex-2-enonic Acid g-Lactone D-erythro-Hex-2-enonic acid, γ-lactone D-Isoascorbic acid Erycorbin Erythorbic acid [Wiki] Glucosaccharonic acid KF3015000 Mercate "5" Mercate 5 MFCD00005378 [MDL number] Saccharosonic Acid (2R)-2-[(1R)-1,2-dihydroxyethyl]-3,4-dihydroxy-2H-furan-5-one (5R)-5-(1,2-dihydroxyethyl)-3,4-dihydroxy-5-hydrofuran-2-one (5R)-5-[(1R)-1,2-dihydroxyethyl]-3,4-dihydroxy-2,5-dihydrofuran-2-one (R)-5-((R)-1,2-dihydroxyethyl)-3,4-dihydroxyfuran-2(5H)-one [89-65-6] 2,3-Didehydro-D-erythro-hexono-1,4-lactone 6381-77-7 [RN] Araboascorbic acid D-(-)-Araboascorbic acid D(-)-Isoascorbic acid d(-)-isoascorbic acid 98% d(-)-isoascorbic acid, 98% d-(-)-isoascorbic acid, 98% d-(-)-isoascorbicacid D-ARABOASCORBICACID D-Erythorbic acid D-ERYTHRO-HEX-2-ENONIC ACID γ-LACTONE D-erythro-hex-2-enono-1,4-lactone D-Isoascorbic acid|D-Erythorbic acid ISD ISOASCORBIC ACID Isovitamin C UNII:311332OII1 UNII-311332OII1

EDTA, N° CAS : 60-00-4 - Acide éthylène diamine tétraacétique. Nom INCI : EDTA. Nom chimique : 1,2-Ethanediamine, N,N,N',N'-tetrakis(carboxymethyl)-, N° EINECS/ELINCS : 200-449-4, Additif alimentaire : E385. Classification : EDTA. L'EDTA (EDTA et ses principaux sels utilisés en cosmétique Disodium EDTA, Tetrasodium EDTA, Trisodium EDTA) est un agent chélateur que l'on emploie depuis les années 30 et pour lequel les industriels maîtrisent totalement la transformation et l'usage. Sa principale propriété est de complexer les métaux lourds. C'est-à-dire qu'il va en quelque sorte les neutraliser en formant avec eux un complexe, pour leur servir ensuite de transporteur et les évacuer. Il est donc assez logiquement utilisé en médecine pour lutter contre les intoxications aux métaux lourds (au plomb par exemple). Il est souvent employé en tant que séquestrant (calcium, calcaire ...) dans les savons ou gels douches, cela permet notamment de gérer les eaux "dures".Ses fonctions (INCI). Agent de chélation : Réagit et forme des complexes avec des ions métalliques qui pourraient affecter la stabilité et / ou l'apparence des produits cosmétiques. Noms français : (ETHYLENEDINITRILO) TETRAACETIC ACID (ETHYLENEDINITRILO)TETRAACETIC ACID 3,6-BIS(CARBOXYMETHYL)-3,5-DIAZOOCTANEDIOIC ACID 3,6-DIAZAOCTANEDIOIC ACID, 3,6-BIS(CARBOXYMETHYL)- ACETIC ACID, (ETHYLENEDINITRILO)TETRA- ACETIC ACID, 2,2',2'',2'''-(1,2-ETHANEDIYLDINITRILO)TETRAKIS- ACIDE ETHYLENEDIAMINETETRACETIQUE Acide édétique Acide éthylènediaminetétraacétique ETHYLEBISIMINODIACETIC ACID ETHYLENE BIS (IMINODIACETIC ACID) ETHYLENEDINITRILOTETRAACETIC ACID N,N'-1,2-ETHANEDIYLBIS(N-(CARBOXYMETHYL)GLYCINE) Noms anglais : E D T A E.D.T.A. EDTA EDTA (CHELATING AGENT) EDTA ACID ETHYLENE DIAMINE TETRAACETIC ACID ETHYLENEDIAMINE TETRAACETIC ACID ETHYLENEDIAMINE-N,N,N',N'-TETRAACETIC ACID Ethylenediaminetetraacetic acid GLYCINE, N,N'-1,2-ETHANEDIYLBIS(N-CARBOXYMETHYL)- Utilisation et sources d'émission Agent chélateur, agent de dosage analytique

EDTMP, N° CAS : 1429-50-1 - Acide éthylènediaminetétraméthylène phosphonique. Nom INCI : EDTMP. Ses fonctions (INCI), Agent de chélation : Réagit et forme des complexes avec des ions métalliques qui pourraient affecter la stabilité et / ou l'apparence des produits cosmétiques

HYDROXYETHANEDIPHOSPHONIC ACID; HEDP; ETIDRONIC ACID, N° CAS : 2809-21-4 - Acide étidronique, Origine(s) : Synthétique , Nom INCI : ETIDRONIC ACID , Nom chimique : Phosphonic acid, (1-hydroxyethylidene)bis- , N° EINECS/ELINCS : 220-552-8. L'acide étidronique est utilisé en tant qu'agent chélateur dans les cosmétiques. Il crée des complexes avec le calcium, l'arsenic, le fer et autres ions métalliques pour les neutraliser. Cela permet de gérer l'utilisation d'eaux un peu "dures", qui pourraient interférer avec les tensioactifs du produit par exemple. Ses fonctions (INCI) Agent de chélation : Réagit et forme des complexes avec des ions métalliques qui pourraient affecter la stabilité et / ou l'apparence des produits cosmétiques. oms français : (1-HYDROXYETHYLIDENE)BIS(PHOSPHONIC ACID) (1-HYDROXYETHYLIDENE)DIPHOSPHONIC ACID (HYDROXYETHYLIDENE)DIPHOSPHONIC ACID 1-HYDROXYETHANE-1,1-BIPHOSPHONIC ACID 1-HYDROXYETHANE-1,1-DIPHOSPHONIC ACID 1-HYDROXYETHANEDIPHOSPHONIC ACID 1-HYDROXYETHYLIDENE-1,1-DIPHOSPHONIC ACID ACIDE HYDROXY-1 ETHYLIDENE DIPHOSPHONIQUE-1,1 ACIDE HYDROXYETHYLIDENE DIPHOSPHONIQUE EHDP ETHANE-1-HYDROXY-1,1-DIPHOSPHONIC ACID HYDROXYETHANE-1,1-DIPHOSPHONIC ACID OXYETHYLIDENEDIPHOSPHONIC ACID PHOSPHONIC ACID, (1-HYDROXYETHYLIDENE)BIS- PHOSPHONIC ACID, (1-HYDROXYETHYLIDENE)BIS-, PHOSPHONIC ACID, (1-HYDROXYETHYLIDENE)DI-, Noms anglais : ETIDRONIC ACID HYDROXYETHANEDIPHOSPHONIC ACID Utilisation et sources d'émission Agent chélateur

FUMARIC ACID, N° CAS : 110-17-8 - Acide fumarique, Nom INCI : FUMARIC ACID. Nom chimique : Fumaric acid. N° EINECS/ELINCS : 203-743-0. Additif alimentaire : E297. Ses fonctions (INCI). Régulateur de pH : Stabilise le pH des cosmétiques. Noms français : (E)-BUTENEDIOIC ACID 1,2-ETHYLENE DICARBOXYLIC ACID (E) 2-BUTENEDIOIC ACID (E)- 2-BUTENEDIOIC ACID, (E)- ACIDE BOLETIQUE ACIDE BUTENEDIOIQUE (TRANS-) Acide fumarique ACIDE LICHENIQUE BUTENEDIOIC ACID,(E)- TRANS-1,2-ETHYLENE DICARBOXYLIC ACID TRANS-1,2-ETHYLENEDICARBOXYLIC ACID TRANS-BUTENEDIOIC ACID Noms anglais : BOLETIC ACID Fumaric acid LICHENIC ACID Utilisation : Fabrication de résines. Fumaric acid [Wiki] (2E)-2-Butendisäure [German] (2E)-2-Butenedioic acid (2E)-But-2-enedioic acid (E)-1,2-Ethylenedicarboxylic acid (E)-2-Butenedioic acid (E)-Butenedioic acid 1,2-Ethenedicarboxylic acid, trans- 110-17-8 [RN] 203-743-0 [EINECS] 2-Butenedioic acid 2-Butenedioic acid (2E)- 2-Butenedioic acid, (2E)- [ACD/Index Name] 2-Butenedioic acid, (E)- 605763 [Beilstein] Acide (2E)-2-butènedioïque [French] Acidum fumaricum Butenedioic acid, (E)- E-2-Butenedioic acid MFCD00002700 [MDL number] trans-1,2-ethenedicarboxylic acid trans-1,2-ethylenedicarboxylic acid TRANS-2-BUTENEDIOIC ACID trans-but-2-enedioic acid trans-Butenedioic acid (2E)-But-2-enedioate (E)-2-Butenedioate (E)-but-2-enedioate (E)-but-2-enedioic acid (E)-HO2CCH=CHCO2H 1,2-Ethylenedicarboxylic acid, (E) 2-(E)-Butenedioate 2-(E)-Butenedioic acid 2-Butenedioic acid (E)- 4-02-00-02202 [Beilstein] 605762 [Beilstein] Allomaleate Allomaleic acid Allomalenic acid Boletate Boletic acid cis-Butenedioic acid Fumaricum acidum Fumarsaeure Kyselina fumarova [Czech] Lichenate Lichenic acid (VAN) QV1U1VQ-T [WLN] trans-1,2-Ethylenedicarboxylate trans-2-Butenedioate trans-Butenedioate 延胡索酸 [Chinese]

GLUCONIC ACID, N° CAS : 526-95-4 - Acide gluconique. Nom INCI : GLUCONIC ACID. Nom chimique : D-gluconic acid. N° EINECS/ELINCS : 208-401-4. Additif alimentaire : E574. Ses fonctions (INCI). Agent de chélation : Réagit et forme des complexes avec des ions métalliques qui pourraient affecter la stabilité et / ou l'apparence des produits cosmétiques. Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. Noms français : Acide D-gluconique; Acide gluconique; D-GLUCONIC ACID; DEXTRONIC ACID; Gluconic acid; GLUCONIC ACID, D-GLYCOGENIC ACID; GLYCONIC ACID; MALTONIC ACID; PENTAHYDROXYCAPROIC ACID. Noms anglais : Gluconic acid. Utilisation: Additif alimentaire. D-Gluconic acid 1726055 [Beilstein] 2,3,4,5,6-Pentahydroxycaproic acid 208-401-4 [EINECS] 526-95-4 [RN] Acide D-gluconique [French] D-Gluconsäure [German] Gluconic acid Glyconic Acid 2,3,4,5,6-pentahydroxy-hexanoic acid Dextronate Glycogenate Glyconate Maltonate (2R,3S,4R,5R)-2,3,4,5,6-pentahydroxyhexanoic acid (3S,2R,4R,5R)-2,3,4,5,6-pentahydroxyhexanoic acid [526-95-4] 157663-13-3 [RN] 2,3,4,5,6-pentahydroxyhexanoate 2,3,4,5,6-Pentahydroxyhexanoic acid 2-dehydro-3-deoxy-D-gluconate 2-keto-3-deoxy-D-gluconate 50% aqueous solution 50% gluconic acid solution 9025-70-1 [RN] d-(+)-gluconic acid Dextranase Dextronic acid D-gluco-Hexonic acid D-Gluconic acid - 45-50% in water D-Gluconic Acid (50per cent in Water) D-Gluconic acid 50% in water D-Gluconsaeure D-GLUCOSONIC ACID D-Glukonsaeure d-葡萄糖酸溶液 Galactonic acid GCO Glosanto Gluconic Acid (contains Gluconolactone) Gluconic acid (VAN) GLUCONIC ACID, D- gluconicacid Glycogenic acid ketogluconic acid Maltonic acid Pentahydroxycaproate Pentahydroxycaproic acid UNII:R4R8J0Q44B UNII-R4R8J0Q44B 葡萄糖酸 [Chinese]

GLUTAMIC ACID, N° CAS : 56-86-0 - Acide glutamique. Origine(s) : Synthétique. Autres langues : Acido glutammico, Glutaminsäure, Ácido glutamico. Nom INCI : GLUTAMIC ACID. Nom chimique : (S)-2-Aminopentanedioic acid. N° EINECS/ELINCS : 200-293-7. Additif alimentaire : E620. Ses fonctions (INCI). Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Conditionneur capillaire : Laisse les cheveux faciles àcoiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance. Humectant : Maintient la teneur en eau d'un cosmétique dans son emballage et sur la peau

GLUTARIC ACID, N° CAS : 110-94-1. Nom INCI : GLUTARIC ACID. Nom chimique : 1,3-Pentanedioic acid. N° EINECS/ELINCS : 203-817-2. Ses fonctions (INCI): Régulateur de pH : Stabilise le pH des cosmétiques. Noms français : 1,3-PROPANEDICARBOXYLIC ACID; 1,5-PENTANEDIOIC ACID; Acide glutarique; ACIDE PENTANEDIOIQUE; ACIDE PENTANEDIOIQUE-1,5; ACIDE PROPANEDICARBOXYLIQUE-1,3; Glutaric acid; PENTANEDIOIC ACID. Noms anglais : Glutaric acid. Utilisation: Fabrication de produits organiques. 1,3-Propanedicarboxylic acid. Glutaric acid ; 1,3-Propanedicarboxylate; 1,5-Pentanedioate; 1,5-Pentanedioic acid; 110-94-1 [RN]; 1209725 [Beilstein]; 203-817-2 [EINECS]; Acide glutarique [French] ; Glutarsäure hydrogen glutarate; MFCD00004410 [MDL number]; n-Pyrotartaric acid; Pentanedioic acid [ACD/Index Name]; 1,3-PROPANEDICARBOXYLIC ACID; 111-16-0 [RN]; 203-817-2MFCD00004410 271-678-5 [EINECS] 273-081-5 [EINECS] 4-02-00-01934 (Beilstein Handbook Reference) [Beilstein] 68603-87-2 [RN] 68937-69-9 [RN] 8065-59-6 [RN] Glutaric acid (Pentanedioic acid) glutaric acid, reagent Pentandioate Pentandioic acid pentanedioate Propane-1,3-dicarboxylic acid Propane-1,3-dicarboxylic acid|Pentanedioic acid,Glutaric acid WLN: QV3VQ 戊二酸 [Chinese] 1,5-Pentanedioic acid Glutaric acid n-Pyrotartaric acid Pentandioic acid CAS names Pentanedioic acid CH02923 Glutarsäure pentanedioic acid.

Glycol acid; GLYCOLIC ACID; N° CAS : 79-14-1 - Acide glycolique, Origine(s) : Végétale, Synthétique. Nom INCI : GLYCOLIC ACID. Nom chimique : Acetic acid, hydroxy-, N° EINECS/ELINCS : 201-180-5, L'acide glycolique est un acide organique naturel, aussi nommé acides alpha-hydroxylés (AHA). Il est généralement fabriqué àpartir de canne àsucre. Il est utilisé dans les peeling doux et produits exfoliants àbase d'acide. Il permet d'accélérer la perte des cellules mortes et favorise le renouvellement cellulaire. Comme les autres acides de fruits, on l'emploie aussi pour lisser les rides, éclaircir le teint, estomper les tâches pigmentaires et les irrégularités de la peau.Ses fonctions (INCI): Régulateur de pH : Stabilise le pH des cosmétiques. Noms français : Acide glycolique; ACIDE; HYDROXYACETIQUE; HYDROXY ACETIC ACID; Hydroxyacetic acid; HYDROXYETHANOIC ACID. Noms anglais : Glycolic acid. Utilisation: Fabrication de produits textiles, fabrication de produits organiques. 1209322 [Beilstein]; 201-180-5 [EINECS]; 2-Hydroxyethanoic acid; 79-14-1 [RN]; Acetic acid, 2-hydroxy- [ACD/Index Name];Acide glycol [French] [ACD/IUPAC Name] Acide hydroxyacétique [French]; a-Hydroxyacetic acid; Glycol acid [ACD/IUPAC Name] Glycolic acid Glycolsäure [German] Hydroxyessigsäure [German] [ACD/IUPAC Name] Kyselina glykolova [Czech] Kyselina hydroxyoctova [Czech] QV1Q [WLN] 1,2-Ethanediol [ACD/Index Name] 102962-28-7 [RN] 1-hydroxy-ethanoic acid 26009-03-0 [RN] 2-oxonioacetate D-malate EDO GLV Glycocide Glycolic acid, 66-70% aqueous solution glycolic acid, crystal, reagent Glycolic acid, pure, 99.5% Glycollic acid Glyoxylic acid GOA HOCH2COOH Hydroxy-acetic acid Hydroxyethanoic acid Kyselina glykolova MFCD00868116 [MDL number] MLT TAR WLN: QV1Q α-Hydroxyacetic acid α-Hydroxyacetic acid 乙醇酸 [Chinese]. Acetic acid, 2-hydroxy- Acetic acid, hydroxy- Glycollic acid Hydroxyacetic acid Hydroxyethanoic acid Kyselina glykolova Kyselina hydroxyoctova Translated names Acid glicolic (ro) Acide glycolique (fr) Acido glicolico (it) Aċidu glikolliku (mt) Glikolio rūgštis (lt) Glikolna kiselina (hr) Glikolna kislina (sl) Glikolsav (hu) Glikolskābe (lv) Glycolic acid (no) glycolsyre (da) Glycolzuur (nl) Glykolihappo (fi) glykolová kyselina/2-hydroxyethanová kyselina (cs) Glykolsyra (sv) Glykolsäure (de) Glükoolhape (et) Kwas glikolowy (pl) kyselina glykolová (sk) Ácido glicólico (es) Γλυκολικό οξύ (el) Гликолова киселина (bg) 2-hydroxy acetic acid 2-Hydroxyacetic acid 2-Hydroxyethanoic acid glycol acid Glykolsäure ... %

Cas : 67701-05-7, EC : 266-929-0, Fatty acids, C8-18 and C18-unsatd.

hyaluronan, HYALURONIC ACID, N° CAS : 9004-61-9 - Acide hyaluronique,Autres langues : Acido ialuronico, Hyaluronsäure, Ácido hialurónico, Nom INCI : HYALURONIC ACID, Nom chimique : Hyaluronic acid. N° EINECS/ELINCS : 232-678-0. Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Humectant : Maintient la teneur en eau d'un cosmétique dans son emballage et sur la peau. Hydratant : Augmente la teneur en eau de la peau et aide àla maintenir douce et lisse. Agent d'entretien de la peau : Maintient la peau en bon état

HYDROLYZED HYALURONIC ACID, Acide hyaluronique hydrolysé, Nom INCI : HYDROLYZED HYALURONIC ACID. Ses fonctions (INCI) : Conditionneur capillaire : Laisse les cheveux faciles àcoiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance. Humectant : Maintient la teneur en eau d'un cosmétique dans son emballage et sur la peau. Agent d'entretien de la peau : Maintient la peau en bon état

ARACHIDIC ACID, Icosa-5,8,11,14-tetraenoic acid; N° CAS : 506-30-9 - Acide icosanoïque ou acide arachidique, Nom INCI : ARACHIDIC ACID, Nom chimique : Icosanoic acid, N° EINECS/ELINCS : 208-031-3. Noms français :Acide arachidique; ACIDE EICOSANOIQUE; EICOSANOIC ACID. Noms anglais : ARACHIC ACID; Arachidic acid; Utilisation: Produit organique, Agent nettoyant : Aide àgarder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Opacifiant : Réduit la transparence ou la translucidité des cosmétiques. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue àla répartition uniforme du produit lors de son utilisation. 208-031-3 [EINECS] 506-30-9 [RN] Acide icosanoïque [French] ácido n-eicosanoico [Spanish] Arachic acid Arachidic acid Arachidinic acid Arachinsaeure [German] Eicosanoic acid Icosanoic acid Icosansäure [German] 5,8,11-Eicosatriynoic Acid|5,8,11-eicosatriynoic acid ACD arachidic acid, 98% Arachidic acid;Eicosanoic acid Arachidic Acid|eicosanoic acid ARACHIDIC ACID|ICOSANOIC ACID arachidicacid Arachinsaeure Eicosanic acid Eicosanoic acid (Arachidic acid) eicosanoic acid, 99% Eicosanoicacid Eicosatetraynoic Acid|5,8,11,14-eicosatetraynoic acid ethyl stearic acid icosanoicacid

maleicacid; Maleinic acid; Malenic acid; Maleic acid; MALEINIC ACID; MALENIC ACID; TOXILIC ACID; ACIDE MALEINIQUE; ACIDE MALENIQUE; Acide maléique; acide (Z)-but-2-èn-1,4-dioïque, acide Z-butènedioïque, acide maléique, No CAS: 110-16-7, Nom INCI : MALEIC ACID.ácido maleico; Allomaleic acid; Allomalenic acid ;Nom chimique : 2-Butenedioic acid (2Z)-. N° EINECS/ELINCS : 203-742-5. Ses fonctions (INCI) : Régulateur de pH : Stabilise le pH des cosmétiques. L'acide maléique est un acide dicarboxylique insaturé, l'acide Z-butènedioïque. Cette molécule est le diastéréoisomère de l'acide fumarique ou acide E-butènedioïque, la configuration montre que les groupements carboxyles, caractéristiques des acides organiques sont placés sur un plan du même côté de la liaison éthylénique, c'est-à-dire de la double liaison carbone-carbone, rigide. Les sels de ses anions et les esters sont appelés maléates.Noms français : (Z)-BUTEDIOIC ACID; 1,2-ETHYLENEDICARBOXYLIC ACID, (Z); 2-BUTENEDIOIC ACID (Z)-; ACIDE BUTENEDIOIQUE (CIS-); ACIDE MALEINIQUE; ACIDE MALENIQUE; Acide maléique; CIS-1,2-ETHYLENEDICARBOXYLIC ACID; CIS-BUTENEDIOIC ACID.Noms anglais : Maleic acid; MALEINIC ACID; MALENIC ACID; TOXILIC ACID. Utilisation : Fabrication de produits organiques et de résines; Maleic acid; (2Z)-2-Butendisäure [German] [ACD/IUPAC Name]; (2Z)-2-Butenedioic acid [ACD/IUPAC Name]; (2Z)-But-2-enedioic acid; 110-16-7 [RN]; 2-Butenedioic acid, (2Z)- [ACD/Index Name]; 605762 [Beilstein]; Acide (2Z)-2-butènedioïque [French] [ACD/IUPAC Name]; Acidum maleicum; cis-Butenedioic acid; toxilic acid; trans-but-2-enedioic acid; (2Z)-But-2-ene-1,4-dioic acid; (2Z)-but-2-enedioate; (2Z)but-2-enedioic acid; (2Z)-Butene-2-dioate; (2Z)-Butene-2-dioic acid; (Z)-1,2-Ethenedicarboxylic Acid; (Z)-2-butenedioate; (Z)-2-Butenedioic acid; (Z)-but-2-enedioic acid; (z)-butenedioate; (Z)-butenedioic acid; 1,2-dihydropyridazine-3,6-dione; 1,2-Ethylenedicarboxylic acid, (Z); 1,2-Ethylenedicarboxylic acid, cis-; 2-Butenedioic acid [ACD/IUPAC Name]; 2-Butenedioic acid (2Z)-; 2-Butenedioic acid (Z)-; 2-Butenedioic acid, (Z)-; ácido maleico; Allomaleic acid; Allomalenic acid; Boletic acid; but-2-enedioic acid; BUTENE-1,4-DIOIC ACID; Butenedioic acid; Butenedioic acid, (Z)-; Butenedioic acid,(Z)-; cis-1,2-ethylenedicarboxylic acid; cis-2-Butenedioate; CIS-2-BUTENEDIOIC ACID; cis-But-2-enedioate; cis-but-2-enedioic acid; Cis-butenedioate; Fumaric acid; H2male; hydrogen maleate; Kyselina maleinova [Czech];Kyselina maleinova; Lichenic acid; MAE; maleic acid reference material; Maleic acid|(2Z)-But-2-ene-1,4-dioic acid; maleic acid-cp; maleicacid; Maleinic acid; Malenic acid; Malezid CM;polymaleic acid; QV1U1VQ-C [WLN]; ZEELCHEM 200;Z-fumaric acid; 馬來酸 [Chinese]; (Z)-but-2-enová kyselina (cs); acid maleic (ro); acide maléique (fr); acido maleico (it); aċidu malejku (mt); kwas maleinowy (pl); kyselina maleínová (sk); Maleiinhape (et); maleiinihappo (fi); maleino rūgštis (lt); maleinová kyselina (cs); maleinsav (hu); maleinska kiselina (hr); maleinska kislina (sl); maleinsyra (sv); maleinsyre (da); Maleinsäure (de); maleïnezuur (nl); maleīnskābe (lv); ácido maleico (es); μηλεϊνικό οξύ (el); малеинова киселина (bg); CAS names: 2-Butenedioic acid (2Z)-; : (2Z)-but-2-enedioic acid; (Z)-But-2-enedioic acid; (Z)-Butenedioic acid; (Z)-Butenedioic acid, Maleic acid; but-2-enedioic acid; but-2-enedioic acid ; cis-1,2-Ethylendicarbonsäure; cis-Butendisäure; cis-Butenedioic acid, Toxilic acid, Acidum maleicum, Butenedioic Acid; Maleic acid (Z)-Butenedioic acid; Maleinsaeure; Maleinsäurelösung; MEXORYL SCO; Trade names: 2-Butenedioic acid (Z)- (9CI); 2-Butenedioic acid, (Z)-; cis-1,2-Ethylenedicarboxylic acid; cis-2-Butenedioic acid; cis-Butenedioic acid; Maleic acid (40% in water); Maleic acid (8CI); Toxilic acid

MERCAPTOPROPIONIC ACID, N° CAS : 107-96-0, Nom INCI : MERCAPTOPROPIONIC ACID. Nom chimique : 3-Mercaptopropionic acid, N° EINECS/ELINCS : 203-537-0. Dépilatoire : Enlève les poils indésirables. Agent bouclant ou lissant (coiffant) : Modifie la structure chimique des cheveux, pour les coiffer dans le style requis. Agent réducteur : Modifie la nature chimique d'une autre substance en ajoutant de l'hydrogène ou en éliminant l'oxygène.beta.-Mercaptopropionic acid.beta.-Thiopropionic acid, 2-Mercaptoethanecarboxylic acid, 3-MERCAPTOPROPANOIC ACID, 3-MERCAPTOPROPIONATE, 3-mercaptopropionic acid, 3-sulfanylpropanoic acid, 3-thiohydracrylic acid, 3-Thiolpropanoic acid, 3-Thiopropanoic acid, 3-THIOPROPIONIC ACID, 3MPA, beta-Mercaptopropanoic acid, beta-Mercaptopropionate. BETA-MERCAPTOPROPIONIC ACID. BETA-THIOPROPIONIC ACID. EINECS 203-537-0. Hydracrylic acid, 3-thio-, Propanoic acid, 3-mercapto- Propanoic acid, 3-mercapto-, coco alkyl esters, Propionic acid, 3-mercapto-, PROPIONIC ACID, 3-MERCPATO-, Propionic acid, mercapto-, USAF E-5

FORMIC ACID, N° CAS : 64-18-6 - Acide méthanoïque ou Acide Formique, Nom INCI : FORMIC ACID, Nom chimique : Formic acid, N° EINECS/ELINCS : 200-579-1; Additif alimentaire : E236. Noms français : Acide formique; ACIDE METHANOIQUE; HYDROGEN CARBOXYLIC ACID; METHANOIC ACID. Noms anglais : AMINIC ACID; Formic acid; FORMYLIC ACID Utilisation: L'acide formique est utilisée notamment : en tant que préservatif pour la nourriture et pour l'ensilage;comme antiseptique dans le brassage;en tant qu'acidulant pour teindre les fibres naturelles et synthétiques; dans le tannage du cuir; pour coaguler le latex dans la production de caoutchouc;comme plastifiant dans certaines résines;en tant que réactif en chimie organique dans la manufacture de fumigants et d'insecticides. 1209246 [Beilstein]; 213-057-3 [EINECS]; 213-129-4 [EINECS]; 231-791-2 [EINECS]; 64-18-6 [RN];Acide formique [French] Acido formico [Italian] Ameisensäure [German] Formic acid [ACD/Index Name] [Wiki] HCOOH [Formula] hydroxidooxidocarbon(.) Kwas metaniowy [Polish] Kyselina mravenci [Czech] Methanoic acid Mierenzuur [Dutch] β-Lactic acid 107-31-3 [RN] 147173-07-7 [RN] 1901013 [Beilstein] 2564-86-5 [RN] 2-trans-indole-3-butyryl-CoA 2-trans-indole-3-butyryl-Coenzyme A 3-hydroxy-indole-3-butyryl-CoA 3-hydroxy-indole-3-butyryl-coenzyme A 3-keto-indole-3-butyryl-CoA 3-keto-indole-3-butyryl-coenzyme A 6'-hydroxyferuloyl-CoA 7056-83-9 [RN] 8006-93-7 [RN] Acetate ion Acetic acid [ACD/Index Name] [Wiki] Add-F Amasil Ameisensaeure [German] Bilorin Carbon dioxide [JP15] [USAN] [USP] [Wiki] CBX Citric acid [Wiki] Collo-bueglatt Collo-didax FMT Formic acid anhydrous Formic Acid, ACS Grade Formic acid-d [ACD/Index Name] Formira Formisoton Formylic acid HOCO(.) http://www.hmdb.ca/metabolites/HMDB0000142 hydrocarboxyl radical Hydrogen carboxylic acid Hydrogencarboxylic acid Hydroxycarbonyl indole-3-acetyl-CoA indole-3-butyryl-CoA Kwas metaniowy Kyselina mravenci Methanol [ACD/Index Name] [Wiki] methoic acid METHOXY, OXO- MFCD00167028 [MDL number] Mierenzuur MOH MONOCARBOXYLIC ACID Myrmicyl Salachlor SEC65 protein Sybest TBF tert-Butyl formate

Acide oléique – 6,7,8 – polyglycolester, Inci : PEG-6 oleate, PEG-4 oleate, PEG-5 oleate, PEG-7 oleate; Cas : 9004-96-0; Oleic acid, ethoxylated; Oleic acid, 12EO; Poly(ethylene glycol) monooleate; Poly(oxy-1,2-ethanediyl), .alpha.-(1-oxo-9-octadecenyl)-.omega.- hydroxy-, (Z)-

PROPIONIC ACID, N° CAS : 79-09-4 - Acide propanoïque. Nom INCI : PROPIONIC ACID. Nom chimique : Propionic acid. N° EINECS/ELINCS : 201-176-3. Additif alimentaire : E280, Classification : Règlementé, Conservateur. Compatible Bio (Référentiel COSMOS). Ses fonctions (INCI) : Conservateur : Inhibe le développement des micro-organismes dans les produits cosmétiques.Noms français : Acide propanoïque; Acide propionique. Noms anglais : Carboxyethane; Ethanecarboxylic acid; Ethylformic acid; Metacetonic acid; Methyl acetic acid; Propanoic acid; Propionic acid; Pseudoacetic acid. Utilisation et sources d'émission: Fabrication de produits organiques et pharmaceutiques; Noms français : Acide propanoïque; Acide propionique. Noms anglais : Carboxyethane ; Ethanecarboxylic acid; Ethylformic acid; Metacetonic acid; Methyl acetic acid; Propanoic acid; Propionic acid; Pseudoacetic acid; Utilisation et sources d'émission: Fabrication de produits organiques et pharmaceutiques. Antischim B; C3 acid; Carboxyethane; Ethanecarboxylic acid; Ethylformic acid; Kyselina propionova; Luprosil; Metacetonic acid; Methyl acetic acid; Monoprop; Propionic acid (natural); propionic acid ... %; Propionic acid grain preserver; PROPIONIC ACID ; propionic acid ; Prozoin; Pseudoacetic acid; Sentry grain preserver; Tenox P grain preservative . Translated names: propiono rūgštis (lt); Acid propionic (ro); acid propionic … % (ro); Acide propionique (fr); acide propionique ... % (fr); Acido propionico (it); acido propionico ... % (it); Aċidu propjoniku (mt); kwas etanokarboksylowy ...% (pl); kwas metylooctowy ...% (pl); Kwas propionowy (pl); kwas propionowy ...% (pl); Kyselina propionová (cs); Kyselina propiónová (sk); Propano rūgštis (lt); propansyra ... % (sv); Propionic acid (no); Propionihappo (fi); Propionihappo... % (fi); propionová kyselina ...% (cs);Propionsav (hu); propionsav …% (hu); Propionska kiselina (hr); propionska kiselina ... % (hr); Propionska kislina (sl); propionska kislina...% (sl); Propionskābe (lv); Propionsyra (sv); propionsyra ... % (sv); Propionsyre (da); propionsyre ... % (da); Propionsäure (de); Propionsäure ... % (de); Propionzuur (nl); propionzuur ... % (nl); Propioonhape (et); Propioonhape … % (et); propánová kyselina ... % (sk); Ácido propiónico (es); ácido propiónico ... % (es); Προπιονικό οξύ (el); προπιονικό οξύ ... % (el); Пропионова киселина (bg); пропионова киселина... % (bg); % propionskābe (lv). CAS names: Propanoic acid. : Acid C3, Propanoic acid, Propanyl acid, Methyl acetic acid; n-Propionic Acid; propionic acid...%. Trade names: Adofeed; Carboxylic acid c3; E 280; Fema number 2924; Methylacetic acid; N-propanoic acid; Propanoic acid (9CI); Propcorn; Propionic acid (6CI, 8CI); Propionsaeure; Propkorn

STEARIC ACID, N° CAS : 57-11-4 - Acide stéarique, Origine(s) : Végétale, Animale, Synthétique,Autres langues : Acido stearico, Stearinsäure, Ácido esteárico. Nom INCI : STEARIC ACID, Nom chimique : Stearic acid, N° EINECS/ELINCS : 200-313-4, Additif alimentaire : E570. Ses fonctions (INCI). Agent nettoyant : Aide àgarder une surface propre; Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Stabilisateur d'émulsion : Favorise le processus d'émulsification et améliore la stabilité et la durée de conservation de l'émulsion. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Agent de restauration lipidique : Restaure les lipides des cheveux ou des couches supérieures de la peau Tensioactif : Réduit la tension superficielle des cosmétiques et contribue àla répartition uniforme du produit lors de son utilisation; Noms français : Acide octadécanoïque ; Acide stéarique. Noms anglais :1-Heptadecane carboxylic acid; 1-Heptadecanecarboxylic acid; Octadecanoic acid; Stearic acid. Utilisation et sources d'émission: Fabrication de produits pharmaceutiques et de savons; Stearic acid EC Inventory, , , EU. Com. Reg. No 10/2011 on plastic materials in contact with food CAS names : Octadecanoic acid. IUPAC names; acide octadécanoïque; Stearic acid (even numbered); Stearic Acid C18; stearic acid; Octadecanoic acid

SUCCINIC ACID, N° CAS : 110-15-6 - Acide succinique, Nom INCI : SUCCINIC ACID, Nom chimique : Butanedioic acid, N° EINECS/ELINCS : 203-740-4.Additif alimentaire : E363. Compatible Bio ; Ses fonctions (INCI). Régulateur de pH : Stabilise le pH des cosmétiques. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit; Noms français : 1,2-ETHANE DICARBOXYLIC ACID; 1,2-ETHANEDICARBOXYLIC ACID; 1,4-BUTANEDIOIC ACID; ACIDE BUTANEDIOIQUE-1,4; Acide succinique; BUTANEDIOIC ACID; DIHYDROFUMARIC ACID; ETHYLENE DICARBOXYLIC ACID. Noms anglais : Succinic acid. Utilisation et sources d'émission : Fabrication de laques, fabrication de colorants; 1,2-Ethanedicarboxylic acid; 1,4-Butanedioic acid ; Acidum succinicum; Amber acid; Asuccin; Bernsteinsaure; Butandisaeure; Dihydrofumaric acid; Ethylene dicarboxylic acid; Ethylenesuccinic acid; Katasuccin; Kyselina jantarova Succinate ; Succinic acid; Succinicum acidum; Wormwood acid. CAS names: Butanedioic acid. IUPAC names : Butanedionic acid; Ethanedicarboxylic acid; Succinic; 1,2-Ethanedicarboxylic acid ; 1,4-Butanedioic acid; 110-15-6 [RN]; 203-740-4 [EINECS]; 4-02-00-01908 [Beilstein]; Acide butanedioique [French]; Acide succinique [French] ; Acido succinico [Italian]; ácido succínico [Spanish]; Ácido succínico [Portuguese]; acidum succinicum [Latin]; Bernsteinsaeure [German]; Bernsteinsäure [German] ; Butanedioic acid ; HOOC-CH2-CH2-COOH [Formula]; Kyselina jantarova [Czech]; MFCD00002789 [MDL number]; Succinic acid ; Succinic acid; Ηλεκτρικό οξύ ; Янтарная кислота [Russian]; コハク酸 [Japanese]; 琥珀酸 [Chinese]; acidum succinicum amber acid; asuccin; Bernsteinsaeure; Bernsteinsaure; Butandisaeure; BUTANE DIACID; BUTANEDIOICACID; Dihydrofumaric acid; Ethanedicarboxylic acid; Ethylene dicarboxylic acid ; Ethylene succinic acid; FMR; fum; Fumaric acid ; Katasuccin; Kyselina jantarova; Sal succini; Succinellite; succinic acid(free acid); succunic acide; Wormwood acid

L'acide sulfonique est un acide hypothétique de formule chimique HSO2OH. C'est un tautomère instable de l'acide sulfureux HO-SO-OH. C'est un composé instable qui présente peu d'intérêt en tant que tel, mais il existe de nombreux composés stables en dérivant, de formules chimiques R-SO2OH, pour lesquelles le groupement fonctionnel -SO2OH est appelé fonction acide sulfonique, le composé dans son ensemble étant appelé de manière générale un acide sulfonique.

TARTARIC ACID, N° CAS : 133-37-9 / 147-71-7 / 87-69-4 - Acide tartrique. Autres langues : Acido tartarico, Weinsäure, Ácido tartárico. Nom INCI : TARTARIC ACID. Nom chimique : 2,3-Dihydroxybutanedioic acid, N° EINECS/ELINCS : 205-105-7 / 205-695-6 / 201-766-0. Additif alimentaire : E334. Compatible Bio (Référentiel COSMOS). Ses fonctions (INCI). Régulateur de pH : Stabilise le pH des cosmétiques. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit; Noms français : (+-)-Acide tartarique; (+-)-Acide tartrique; Acide dihydroxy-2,3 ; butanedioïque; Acide DL-tartarique; Acide DL-tartrique; Acide paratartarique; Acide tartarique; Acide tartarique (DL-); Acide tartarique racémique. Acide tartrique. Noms anglais : (+-)-Tartaric acid ; 2,3-Dihydroxybutanedioic acid; DL-Tartaric acid; Paratartaric acid; Racemic acid; Racemic tartaric acid; Resolvable tartaric acid; Tartaric acid; Tartaric acid, (+-)-; Uvic acid; Utilisation et sources d'émission : Fabrication de produits de tannage, additif alimentaire; (±)-tartaric acid. IUPAC names : (+-)-Tartaric acid; (2R,3R)-2,3-dihydroxybutanedioic acid ; 2, 3-Dihydroxybutanedioic Acid; 2,3 dihydroxybutanedioic acid; 2,3-Dihydroxybutanedioic acid; 2,3-dihydroxysuccinic acid; Acide Tartrique Poudre; Butanedioic acid, 2,3-dihydroxy-, (2R,3R)-rel-; DL-Tartaric Acid; Tartaric acid; L-(+)-Tartaric acid; (+)-(2R,3R)-Tartaric acid; (+)-(R,R)-tartaric acid; (+)-L-tartaric acid; (+)-tartaric acid; (2R,3R)-(+)-Tartaric acid; (2R,3R)-2,3-Dihydroxybernsteinsäure [German] [ACD/IUPAC Name]; (2R,3R)-2,3-dihydroxybutanedioic acid; (2R,3R)-2,3-Dihydroxysuccinic acid [ACD/IUPAC Name]; (2R,3R)-tartaric acid (R,R)-(+)-tartaric acid; (R,R)-tartaric acid; [R-(R*,R*)]-2,3-Dihydroxybutanedioic Acid; 133-37-9 [RN]; 1725147 [Beilstein]; 201-766-0 [EINECS]; 205-105-7 [EINECS]; 87-69-4 [RN]; Acide (2R,3R)-2,3-dihydroxysuccinique [French] [ACD/IUPAC Name]; Acidum tartaricum; Butanedioic acid, 2,3-dihydroxy-, (2R,3R)- [ACD/Index Name]; Butanedioic acid, 2,3-dihydroxy-, (2R,3R)-rel- ; L-(+)-Tartarate; L-(+)-Tartrate; L-2,3-Dihydroxybutanedioic Acid; L-tartaric acid; L-threaric acid; MFCD00064207 [MDL number]; Ordinary Tartaric Acid; Tartarate [ACD/IUPAC Name] Tartaric acid [ACD/IUPAC Name] ; Weinsaure [German]; Weinsteinsaure [German]; (+)-tartarate; (2R,3R)-Tartarate; (R,R)-tartarate;(R,R)-tartrate; 2,3-dihydroxybutanedioate; 2,3-dihydroxy-succinate; 2,3-dihydroxysuccinic acid; 2,3-Dihydroxy-succinic acid; L-tartarate; tartrate ; Weinsaeure; (+)-Weinsaeure; (1R,2R)-1,2-Dihydroxyethane-1,2-dicarboxylic acid; (2R,3R)-(+)-2,3-Dihydroxybutane-1,4-dioic acid, (2R,3R)-(+)-2,3-Dihydroxysuccinic acid; (2R,3R)-2,3-Dihydroxybernsteinsaeure ;(2R,3R)-2,3-dihydroxybutanedioate (2R,3R)-2,3-tartaric acid (2R,3R)-rel-2,3-Dihydroxybutanedioic acid (2R,3R)-rel-2,3-Dihydroxysuccinic acid (R,R)-(+)-tartatic acid 1,2-DIHYDROXYETHANE-1,2-DICARBOXYLIC ACID 138508-61-9 [RN] 144814-09-5 [RN] 147-71-7 [RN] 2,3-dihydrosuccinic acid 2,3-dihydroxybutanedioic acid 205-695-6 [EINECS] 39469-81-3 [RN] 3-hydroxymalic acid 4231301 [Beilstein] 526-83-0 [RN] 526-83-087-69-4 56959-20-7 [RN] 69-72-7 [RN] ACS D(-)-TARTARIC ACID D-(-)-Tartaric Acid (en) Dl-dihydroxysuccinic acid hydrogen (2R,3R)-tartrate l-​(+)​-​tartaric acid l-( )-tartaric acid L-(+) tartaric acid L(+)-Tartaric acid L-(+)-Tartaric acid, ACS l-(+)-tartaric acid, anhydrous L(+)-Tartaricacid L-(+)-Tartaricacid lamB protein (fungal) l-tartaricacid l-酒石酸 Metatartaric acid MFCD00071626 [MDL number] R,R-tartaric acid Rechtsweinsaeure TAR Tartaric acid (TN) THREARIC ACID TLA Weinsteinsaeure

MYRISTIC ACID, N° CAS : 544-63-8 - Acide tétradécanoïque (Acide myristique), Acide tetradécanoïque .Synonymes : 1-TRIDECANECARBOXYLIC ACID;ACIDO MYNISTICO;Butter acids;Coconut oil fatty acids;CRODACID;EMERY 655;HYDROFOL ACID 1495;Hystrene 9014;Myristic acid, pure;Myristinsaeure;N-TETRADECAN-1-OIC ACID;N-TETRADECANOIC ACID;N-TETRADECOIC ACID;neo-Fat 14;TETRADECANSAEURE;UNIVOL U 316S.Nom INCI : MYRISTIC ACID. Nom chimique : Tetradecanoic acid. N° EINECS/ELINCS : 208-875-2. Agent nettoyant : Aide àgarder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. Noms français : 1-TRIDECANECARBOXYLIC ACID; Acide myristique; ACIDE TETRADECANOIQUE; ACIDE TETRADECANOIQUE NORMAL; ACIDE TETRADECANOIQUE-1; N-TETRADECAN-1-OIC ACID; N-TETRADECANOIC ACID; N-TETRADECOIC ACID; NORMAL-TETRADECANOIC ACID. Noms anglais :Myristic acid; TETRADECANOIC ACID. Utilisation et sources d'émission: Fabrication de parfums et de savons. 1-tetradecanoic acid; 1-Tridecanecarboxylic acid; 208-875-2 [EINECS]; 508624 [Beilstein]; 544-63-8 [RN];Acide myristique [French] [ACD/IUPAC Name]; Acide tétradécanoïque [French]; myristic acid [ACD/IUPAC Name]; Myristinsäure [German] [ACD/IUPAC Name]; n-Myristic acid; n-TETRADECANOIC ACID; Tetradecanoic acid [ACD/Index Name]; 1-Tridecanecarboxylate; n-Tetradecan-1-oaten-Tetradecanoate; 1,2-DIMYRISTOYL-RAC-GLYCERO-3-PHOSPHOCHOLINE; 12-O-Tetradecanoylphorbol 13-acetate; 12-Tetradecanoylphorbol 13-acetate; 13-Tetradecynoic acid [ACD/Index Name] [ACD/IUPAC Name]; 1-tetradecanecarboxylate; 1-tetradecanecarboxylic acid; 4-02-00-01126 [Beilstein]; 82909-47-5 [RN]; Crodacid; Methyl 11-methyldodecanoate [ACD/IUPAC Name]; Myristic Acid 655; Myristinsaeure; Myristoate; Myristoic acid; n-Tetradecan-1-oic acid; n-tetradecoate; n-Tetradecoic acid; QV13 [WLN]; tetradecanoate; TetradecanoicAcid; tetradecoate; tetradecoic acid

mercaptoacetic acid; Acide thioglycolique; 2-MERCAPTOACETIC ACID; THIOGLYCOLIC ACID, N° CAS : 68-11-1 - Acide thioglycolique et ses sels, Nom INCI : THIOGLYCOLIC ACID, Nom chimique : Mercaptoacetic acid, N° EINECS/ELINCS : 200-677-4; Classification : Règlementé. L'acide thioglycolique modifie les fibres des cheveux pour faciliter leur restructuration : on l'utilise par exemple dans les produits restructurant capillaires. On l'emploie aussi pour décomposer chimiquement les poils indésirables pour qu'ils puissent ensuite être éliminés en les essuyant simplement. C'est son sel de potassium qui est le plus utilisé aujourd'hui.Ses fonctions (INCI). Antioxydant : Inhibe les réactions favorisées par l'oxygène, évitant ainsi l'oxydation et la rancidité. Dépilatoire : Enlève les poils indésirables. Agent bouclant ou lissant (coiffant) : Modifie la structure chimique des cheveux, pour les coiffer dans le style requis. Agent réducteur : Modifie la nature chimique d'une autre substance en ajoutant de l'hydrogène ou en éliminant l'oxygène. Noms français : 2-MERCAPTOACETIC ACID; 2-MERCAPTOETHANOIC ACID; 2-THIOGLYCOLIC ACID; ACIDE MERCAPTO-2 ACETIQUE; ACIDE MERCAPTO-2 ETHANOIQUE; ACIDE MERCAPTOACETIQUE; ACIDE THIO-2 GLYCOLIQUE; Acide thioglycolique; ALPHA-MERCAPTOACETIC ACID; MERCAPTOACETIC ACID; Noms anglais : ACETIC ACID, MERCAPTO-; Thioglycolic acid; THIOGLYCOLLIC ACID; THIOVANIC ACID. Utilisation: L'acide thioglycolique est un produit utilisé dans une grande variété d'applications, dont les cosmétiques, la fabrication des plastiques et la chimie analytique. Il est utilisé notamment: en coiffure pour l'ondulation permanente des cheveux; en tant qu'ingrédient dans des produits capillaires; pour faire des produits dépilatoires; dans certains produits pharmaceutiques; pour faire des thioglycolates utilisés dans l'industrie du plastique (emballages, additifs pour le PVC); pour modifier la laine ou le cuir; en chimie analytique pour différents procédés (par exemple la séparation de l'aluminium du fer); 2-Mercaptoacetate; 2-Mercaptoacetic acid; 2-Thioglycolic acid; Acetic acid, 2-mercapto-; Acetic acid, mercapto-; Glycolic acid, 2-thio-; Glycolic acid, thio-; Kyselina merkaptooctova; Kyselina thioglykolova; Mercaptoacetic acid; Mercaptoessigsaeure; Salts of Thioglycolic acid; Thioglycolate; THIOGLYCOLIC ACID; Thioglycollic acid; Thiovanic acid. Translated names: acid tioglicolic (ro); acide mercaptoacétique (fr); acide thioglycolique (fr); acido tioglicolico (it); kwas 2-sulfanylooctowy (pl); kwas merkaptooctowy (pl); kwas tioglikolowy (pl); kyselina tioglykolová (sk); mercaptoeddikesyre (da); merkaptoacto rūgštis (lt); merkaptoeddiksyre (no); merkaptoättiksyra (sv); thioglycolsyre (da); thioglycolzuur (nl); thioglykolová kyselina (cs); Thioglykolsäure (de); kiselina (hr); tioglikolna kislina (sl);tioglikolsav, merkaptoecetsav (hu); tioglikolskābe (lv); Tioglykolihappo (fi); tioglykolsyra (sv); tioglykolsyre (no); Tioglükoolhape (et); ácido mercaptoacético (es); ácido tioglicólico (es); θειογλυκολικό οξύ (el); тиогликолова киселина (bg).IUPAC names: 2-Sulfanylacetic acid; sulfanylacetic acid; Thioglycolic acid TGA, mercaptoacetic acid; THIOGLYKOLSAEURE. Trade names : Thio Glycolic Acid; Thioglycolic Acid 70%, technical grade; Thioglycolic Acid 80%, cosmetic grade; Thioglycolic Acid 80%, cosmetic grade, low odor; Thioglycolic Acid 80%, pure; Thioglycolic Acid 80%, technical grade; Thioglycolic Acid 85% cosmetic grade; Thioglycolic Acid 85%, technical grade; Thioglycolic Acid 97%, technical grade; Thioglycolic Acid 98%; Thioglycolic Acid 98%, commercial grade; Thioglycolic Acid 99% pure; Thioglycolic Acid 99%, cosmetic grade, low odor; Thioglycolic Acid 99%,cosmetic grade; 200-677-4 [EINECS]; 2-Mercaptoacetic acid; 2-mercaptoethanoic acid; 2-thioglycolic acid; 506166 [Beilstein]; 68-11-1 [RN]; Acetic acid, 2-mercapto- [ACD/Index Name]; acetic acid, mercapto-; acetyl mercaptan; Acide sulfanylacétique [French] ;Acide thioglycolique [French]; Glycolic acid, 2-thio-; Glycolic acid, thio-; Kyselina merkaptooctová [Czech]; Kyselina thioglykolová [Czech]; mercaptoacetic acid; Mercaptoessigsaeure [German]; mercaptoethanoic acid; Merkaptoessigsaeure [German]; MFCD00004876 [MDL number]; Sulfanylacetic acid [ACD/IUPAC Name]; Sulfanylessigsäure [German] ;Thioglycolic acid; thioglycolic acid; thioglycollic acid; Thioglykolsaeure [German]; α-mercaptoacetic acid; 2-sulfanylacetic acid; 2-sulfanylethanoic acid; Acetic acid; Acide thioglycolique; Acide thioglycolique [French]; Kyselina merkaptooctova [Czech]; Kyselina thioglykolova [Czech]; mercapto acetic acid; METHYLTHIO, CARBOXY-; SH1VQ [WLN]; sJPhLPDIKTp@; Thioglycolicacid; Thiovanic acid; WLN: SH1VQ; α-mercaptoacetic acid; α-Mercaptoacetic acid; 巯基乙酸 [Chinese]

EC / List no.: 287-494-3; CAS no.: 85536-14-7; Mol. formula: C19H32O3S; Acide Linear alkyl benzène sulfonique ( labsa ) Linear alkyl benzène acide sulfonique est un grand tensioactif synthétique de volume en raison de son coût relativement faible , de bonnes performances , le fait qu'il peut être séché pour obtenir une poudre stable et le respect de l'environnement biodégradable. 2-Dodecylbenzenesulfonic acid; 4-(tridecan-3-yl)benzene-1-sulfonic acid; 4-Alkylbenzenesulfonic acid; Alkylbenzene C10-C13 sec , sulfonation product with sulphur trioxide; Benzenesulfonic acid; Benzenesulfonic acid, 4-C1-13-sec-alkyl derivs.; Benzenesulfonic Acid, 4-C10-13-Sec-Alkyl Derivatives; Benzenesulfonic acid, 4-C10-13-sec-alkyl derivs; Benzenesulfonic acid, 4-C10-13-sec-alkyl derivs..; Benzenesulfonic acid, 4-C10-13-sec-alkyl derivs.H; Benzesulfonic acid, 4-C10-13-sec-alkyl derivs.; Dodecylbenzene sulfonic acid, mixture of C10-C13 isomers; Dodecylbenzene sulphonic acid; LAB sulpohonic acid, Alkylbenzene sulfonic acid; LABSA; LABSA (Linear Alkylbenzene Sulphonic Acid); Linear alkyl benzene sulfonic acid; Linear Alkyl benzene Sulphonic acid; Linear alkylbenzene sulfonate; Linear Alkylbenzene Sulfonic Acid; Linear alkylbenzene sulphonic acid; Linear alkylbenzenesulphonic acid

COCONUT ACID N° CAS : 61788-47-4 - Acides gras de coco Origine(s) : Végétale Autres langues : Acidi grassi di cocco, Coconut fatty acids, Kokosfettsäuren, Ácidos grasos de coco Nom INCI : COCONUT ACID N° EINECS/ELINCS : 262-978-7 Compatible Bio (Référentiel COSMOS) Ses fonctions (INCI) Agent nettoyant : Aide àgarder une surface propre Emollient : Adoucit et assouplit la peau Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Tensioactif : Réduit la tension superficielle des cosmétiques et contribue àla répartition uniforme du produit lors de son utilisation. MIXED COCONUT FATTY ACIDS Noms anglais : COCONUT OIL FATTY ACIDS FATTY ACIDS, COCO FATTY ACIDS, COCONUT OIL

Acrylic amide; Ethylene Carboxamide; 2-Propenamide; Propenoic acid, amide; Vinyl Amide; Acrylamide ultra sequencing gel, 8%, ready-to-use solution, for biochemistry;Acrylamide, electrophoresis grade, for biochemistry, 99+%;Acrylamide, extra pure, 98.5%;Acrylamide 2X;Acrylamide 4X;SERDOGEL SSCP 2 x Concentrate;ACRYLAMIDE,ULTRAPURE,ELECTROPHORESISGRADE;prop-2-enamide CAS NO:79-06-1

ACRONAL S 790, orta viskoziteli ve mükemmel pigment bağlama özelliğine sahip sulu bir stiren akrilik dispersiyonudur.

ACRONAL S 790, küçük parçacık boyutuna sahip, anyonik orta viskoziteli bir dispersiyondur.
ACRONAL S 790 dolgu maddeleri ile mükemmel uyumluluğa ve yüksek pigment emilimine sahiptir.

Pigmentsiz ACRONAL S 790 filmleri oda sıcaklığında yüzey yapışması göstermez.
Şeffaf, elastik, parlaktırlar, neme ve kire karşı oldukça dayanıklıdırlar.
ACRONAL S 790, alkil fenol etoksilatlara dayalı emülgatörler içermez.

ACRONAL S 790, sızdırmazlık malzemeleri ve astar uygulamaları için standart, üniversal bir bağlayıcıdır.
ACRONAL S 790 iyi bir dolgu uyumluluğu gösterir ve birçok plastikleştirici türüyle uyumludur.

ACRONAL S 790, orta viskoziteye ve mükemmel pigment bağlama gücüne sahip stiren akrilik kopolimerin sulu bir dispersiyonudur.

ACRONAL S 790 APEO içermeyen anyonik stiren akrilik bağlayıcıdır.
Geniş formülasyon aralığına, orta viskoziteye ve çok iyi pigment bağlama kapasitesine sahiptir.

Olağanüstü maliyet performansı ve çok iyi su direnci sunar.
Olağanüstü sabunlaşma ve alkali direncinin yanı sıra üstün kir toplama direnci sergiler.
ACRONAL S 790 mimari kaplamalarda, iç cephe boyalarında, dokulu yüzeylerde, astarlarda, dış cephe yalıtım ve kaplama sistemlerinde (EIFS) ve derz dolgularında kullanılır.

ACRONAL S 790 akrilik dispersiyon, dokunmamış kumaş üretiminde kullanılan bina boyaları (hem dış hem de iç), sıvalar ve dolgu maddeleri, yapıştırıcıların üretimi için bir stiren-akrilik dispersiyondur (akrilik asit ester ve stiren kopolimerin sulu dispersiyonu).

ACRONAL S 790'ın Uygulama Alanı:
ACRONAL S 790'ın bir özelliği de benzersiz özellikleridir.
Bu sayede ACRONAL S 790, sıva, duvar, asbestli çimento, beton, ahşap ve diğer yüzeylere uygulanabilen yüksek parlaklıktan mata kadar bina boyalarının üretiminde kullanılır.

Ayrıca ACRONAL TS 790 üzerinde son derece yüksek pigment kapasitesine sahip olan ACRONAL S 790, yüksek tüketim özelliklerini kaybetmeyen yüksek dolgulu sistemler (boya, sıva, macun vb.) elde etmek mümkün olmakla birlikte, maliyet açısından daha ucuzdur.
Dokunmamış kumaşlar ve tekstil kaplamalar için bağlayıcı olarak ACRONAL S 790, emprenye etme, boyama veya püskürtme yoluyla uygulanır.

ACRONAL S 790 Kullanım Alanları:
Cephe ve iç cephe boyaları
Doku kaplamaları
Mineral yüzeyler için astarlar
macun
Silikat boyaların modifikasyonları
Beton koruma araçları
Mimari kaplamalar
Dokulu yüzeyler
İç cephe boyaları
Dış yalıtım ve kaplama sistemleri (EIFS)
Harçlar
Astarlar

ACRONAL S 790'ın Faydaları:
APEO (Alkilfenol etoksilat) içermez
Yüksek bağlama kapasitesi
Çeşitli yüzeylere iyi yapışma
Düşük su emme
Geniş uygulama yelpazesi

ACRONAL S 790'ın Avantajları:
Geniş formülasyon genişliği
Olağanüstü maliyet-performans oranı
Olağanüstü sabunlaşma ve alkali direnci
Mükemmel su direnci
Üstün kir toplama direnci

ACRONAL S 790'ın İşlenmesi:
Boyalar her zamanki gibi yüksek hızlı çözücülerde üretilir.
Pigmentlerin ve dolgu maddelerinin, dispersiyonu bir alkalin ortama sokmadan önce, ilk olarak ıslatıcı maddeler ve dağıtıcıların (örn. Pigment Dağıtıcılar N veya A veya suda çözünür polifosfatlar) varlığında dağıtılması tavsiye edilir.
Sadece düşük hızlı karıştırıcılarda üretilen yüksek viskoziteli, yüksek katı maddeli ürünlerin (örn. doku kaplamaları ve dolgu maddeleri) üretiminde ACRONAL S 790 yardımcı maddelerle birlikte eklenmelidir.

ACRONAL S 790, yüksek pigment emilimi ve dolgu maddeleri ile mükemmel uyumluluğu ile karakterize edilir.
Karbon karası veya kalsiyum sülfat ve çinko oksit gibi çapraz bağlanması zor olan ve yüksek viskoziteye yol açabilen pigmentler istisnadır.

ACRONAL S 790'ın viskozitesini kontrol etmek ve tüketici özelliklerini optimize etmek için genellikle koyulaştırıcıların eklenmesi gerekir.
En yaygın kullanılan koyulaştırıcılar selüloz eterler, poliakrilat veya diüretan koyulaştırıcılar (örn. Latecoll D veya Collacral PU 75, PU 85, LR 8989, LR 8990) veya bentonitler ve polisakkaritlerdir.
Yoğunlaştırıcının seçimi, bitmiş ürünün nasıl olması gerektiğine bağlıdır (tiksotropik veya daha az viskoz).

Formülasyonları renklendirmek için pigmentler kullanıldığında, özellikle pigment pastaları (örn. Luconyl marka) formunda, ACRONAL S 790 koyulaştırıcının pigmentlerin çökelmesine veya topaklanmasına neden olmayacağından emin olunmalıdır.
Bu nedenle ACRONAL S 790'ın uyumluluk testlerinin (depolama için) yapılması ve gerekirse iyonik olmayan yüzey aktif maddelerin (örn. Lutensol AP 6 dereceleri) eklenmesi önerilir.

Küçük bir LumitenNOC 30 ilavesi, çimento ve kireçle uyumluluğu artırır, sert su uygulamalarında yüksek pigmentli iç cephe boyaları için saklama stabilitesi sağlar ve çalışma aletlerinin temizliğini kolaylaştırır.

20°C'nin altındaki sıcaklıklarda başarılı bir film oluşumu için beyaz ispirto, glikol eterler ve Lusolvan FBH, SolvenonPP gibi birleştiricilerin eklenmesi tavsiye edilir.
Önerilen tüketim yaklaşık %2'dir (toplam hacme göre).

Filmi özellikle esnek hale getirmek için plastikleştiriciler, örneğin Plastilit 3060 veya klorlu parafin veya ftalik asit ester eklenebilir.
ACRONAL S 790'ın şeffaf bir film oluşumunu destekleyen yumuşak dispersiyonlarla (örn. ACRONAL S 400) karıştırmak da mümkündür.

Saf akrilat veya polivinil ester bazlı dispersiyonlarla karıştırmak da mümkündür ancak şeffaf bir film vermez ve herhangi bir teknik avantaj sunmaz.
ACRONAL S 790'ın diğer dispersiyonlarla uyumluluğu, stabilize edici koruyucu bir kolloid olan CollacralVAL'ın eklenmesiyle geliştirildi.

Tüm ince dispersiyonlar gibi ACRONAL S 790 da köpürme eğilimindedir.
Bu nedenle ACRONAL S 790'ın köpük önleyici maddelerin üreticiler tarafından tavsiye edilen miktarlarda (yaklaşık %0,3 - 1) eklenmesi gerekir.
Köpük kesicilerin etkinliği ampirik olarak belirlenmelidir.

ACRONAL S 790 mikroorganizmaların saldırılarına karşı korunmasına rağmen, depolama sırasında stabilitelerini sağlamak için nihai ürünlere koruyucular eklenmelidir.
Kullanılan koruyucunun uyumluluğu ve etkinliği her zaman ampirik olarak test edilmelidir.

Üreticiler ACRONAL S 790'ı kullanarak kendi sıkı ürün geliştirme denemelerini yapmalıdır çünkü denemelerimiz ürün üretimini ve kullanımını etkileyebilecek tüm faktörleri (örn. bileşen uyumluluğu, karıştırma işlemi, çeşitli yüzeylere yapışma vb.) kapsayamaz.
50°C'de saklandıktan sonra viskozite stabilite testleri de yapılmalıdır.

ACRONAL S 790'ın saklanması:
ACRONAL S 790 depolama ve işleme sırasında aşındırıcı metaller veya bunların koruyucu kaplamaları olmayan alaşımlarıyla temas etmemelidir.
Depolama sırasında ürün kapları sıkıca kapatılmalı ve üzerindeki boş hava alanı neme doyurulmalıdır.
ACRONAL S 790 aşırı sıcağa veya donmaya maruz bırakılmamalıdır.

Mikroorganizmalarla ilgili sorunları önlemek için ürün saklama kaplarında hijyen önlemlerine uyulmalıdır.

ACRONAL S 790'ın raf ömrü 10 - 30 °C'de saklandığında 6 aydır.

ACRONAL S 790'ın Güvenliği:
Kimyasalların kullanımıyla ilgili genel gerekliliklere ve yerel endüstriyel hijyen düzenlemelerine uyulmalıdır.
İşleme sırasında etkili havalandırmanın yanı sıra cilt ve gözlük için kişisel koruyucu ekipmanlar da sağlanmalıdır.

ACRONAL S 790'ın Özellikleri:
Dispersiyon tipi: anyonik
Katı içeriği: ca. %50
pH değeri: ca. 7,5 – 9,0
Viskozite1: ca. 700–1.500 mPa·s
Ortalama parçacık boyutu: ca. 0,1 µm
MFFT: ca. 20°C
Özgül ağırlık (dağılım): ca. 1,04 g/cm³
Özgül ağırlık (kuru polimer): ca. 1,08 gr/c

Ürün Kümesi:
Dispersiyonlar

Ürün grubu:
Stiren Akrilikler

Endüstri:
Yapı

Kimyasal türü:
Stiren akrilikler

Diğer ACRONAL Ürünler:
ACRONAL TS 790
ACRONAL 290 D
ACRONAL T 290 D
ACRONAL S 562
ACRONAL S 562 T
ACRONAL ECO 6716
ACRONAL ECO 6716 T
ACRONAL PLUS 6727
ACRONAL S 813
ACRONAL ECO 6258
ACRONAL EDGE 6283
ACRONAL EDGE 6295
ACRONAL A 684
ACRONAL A 754
ACRONAL TA 754
ACRONAL PLUS 6257
ACRONAL DS
ACRONAL DS 6266
ACRONAL ECO 6270
ACRONAL LR 9014
ACRONAL TX 9014

ACRONAL TS 790 orta viskoziteli ve mükemmel pigment bağlama özelliğine sahip sulu stiren akrilik dispersiyonudur.

ACRONAL TS 790, küçük parçacık boyutuna sahip, anyonik orta viskoziteli bir dispersiyondur.
ACRONAL TS 790 dolgu maddeleri ile mükemmel uyumluluğa ve yüksek pigment emilimine sahiptir.

Pigmentsiz ACRONAL TS 790 filmleri oda sıcaklığında yüzey yapışma özelliği göstermez.
Şeffaf, elastik, parlaktırlar, neme ve kire karşı oldukça dayanıklıdırlar.
ACRONAL TS 790, alkil fenol etoksilat bazlı emülgatörler içermez.

ACRONAL TS 790, mastik ve astar uygulamalarına yönelik standart, üniversal bir bağlayıcıdır.
ACRONAL TS 790 iyi bir dolgu uyumluluğu gösterir ve birçok plastikleştirici türüyle uyumludur.

ACRONAL TS 790, orta viskoziteye ve mükemmel pigment bağlama gücüne sahip stiren akrilik kopolimerin sulu bir dispersiyonudur.

ACRONAL TS 790, APEO içermeyen anyonik stiren akrilik bağlayıcıdır.
Geniş formülasyon aralığına, orta viskoziteye ve çok iyi pigment bağlama kapasitesine sahiptir.

Olağanüstü maliyet performansı ve çok iyi su direnci sunar.
Olağanüstü sabunlaşma ve alkali direncinin yanı sıra üstün kir toplama direnci sergiler.
ACRONAL TS 790 mimari kaplamalarda, iç cephe boyalarında, dokulu yüzeylerde, astarlarda, dış cephe yalıtım ve kaplama sistemlerinde (EIFS) ve derz dolgularında kullanılır.

ACRONAL TS 790 akrilik dispersiyon, dokunmamış kumaş üretiminde kullanılan bina boyaları (hem dış hem de iç), sıvalar ve dolgu maddeleri, yapıştırıcıların üretimi için bir stiren-akrilik dispersiyondur (akrilik asit ester ve stiren kopolimerin sulu dispersiyonu).

ACRONAL TS 790'ın Uygulama Alanı:
ACRONAL TS 790'ın bir özelliği de benzersiz özellikleridir.
Bu sayede ACRONAL TS 790, sıva, duvar, asbestli çimento, beton, ahşap ve diğer yüzeylere uygulanabilen yüksek parlaklıktan mata kadar bina boyalarının üretiminde kullanılır.

Ayrıca ACRONAL TS 790 üzerinde son derece yüksek pigment kapasitesine sahip olan ACRONAL S 790, yüksek tüketim özelliklerini kaybetmeyen, yüksek dolgulu sistemler (boya, sıva, macun vb.) elde etmek mümkün olmakla birlikte, maliyet açısından daha ucuzdur.
Nonwoven ve tekstil kaplamalar için bağlayıcı olarak ACRONAL TS 790 emprenye, boyama veya püskürtme yoluyla uygulanır.

ACRONAL TS 790 Kullanım Alanları:
Cephe ve iç cephe boyaları
Doku kaplamaları
Mineral yüzeyler için astarlar
macun
Silikat boyaların modifikasyonları
Beton koruma araçları
Mimari kaplamalar
Dokulu yüzeyler
İç cephe boyaları
Dış yalıtım ve kaplama sistemleri (EIFS)
Harçlar
Astarlar

ACRONAL TS 790'ın Faydaları:
APEO (Alkilfenol etoksilat) içermez
Yüksek bağlama kapasitesi
Çeşitli yüzeylere iyi yapışma
Düşük su emme
Geniş uygulama yelpazesi

ACRONAL TS 790'ın Avantajları:
Geniş formülasyon genişliği
Olağanüstü maliyet-performans oranı
Olağanüstü sabunlaşma ve alkali direnci
Mükemmel su direnci
Üstün kir toplama direnci

ACRONAL TS 790'ın İşlenmesi:
Boyalar her zamanki gibi yüksek hızlı çözücülerde üretilir.
Pigmentlerin ve dolgu maddelerinin, dispersiyonu bir alkalin ortama sokmadan önce, ilk olarak ıslatıcı maddeler ve dağıtıcıların (örn. Pigment Dağıtıcılar N veya A veya suda çözünür polifosfatlar) varlığında dağıtılması tavsiye edilir.
Sadece düşük devirli karıştırıcılarda üretilen yüksek viskoziteli, yüksek katı maddeli ürünlerin (örneğin doku kaplamaları ve dolgu maddeleri) üretiminde ACRONAL TS 790 yardımcı maddelerle birlikte eklenmelidir.

ACRONAL TS 790, yüksek pigment emilimi ve dolgu maddeleri ile mükemmel uyumluluğu ile karakterize edilir.
Karbon karası veya kalsiyum sülfat ve çinko oksit gibi çapraz bağlanması zor olan ve yüksek viskoziteye yol açabilen pigmentler istisnadır.

ACRONAL TS 790'ın viskozitesini kontrol etmek ve tüketici özelliklerini optimize etmek için genellikle koyulaştırıcıların eklenmesi gerekir.
En yaygın kullanılan koyulaştırıcılar selüloz eterler, poliakrilat veya diüretan koyulaştırıcılar (örn. Latecoll D veya Collacral PU 75, PU 85, LR 8989, LR 8990) veya bentonitler ve polisakkaritlerdir.
Yoğunlaştırıcının seçimi, bitmiş ürünün nasıl olması gerektiğine bağlıdır (tiksotropik veya daha az viskoz).

Formülasyonları renklendirmek için pigmentler kullanıldığında, özellikle pigment pastaları (örn. Luconyl markası) kullanıldığında, ACRONAL TS 790 koyulaştırıcının pigmentlerin çökelmesine veya topaklaşmasına neden olmayacağından emin olunmalıdır.
Bu nedenle ACRONAL TS 790'ın uyumluluk testlerinin (depolama için) yapılması ve gerekirse iyonik olmayan yüzey aktif maddelerin (örn. Lutensol AP 6 dereceleri) eklenmesi önerilir.

Küçük bir LumitenNOC 30 ilavesi, çimento ve kireçle uyumluluğu artırır, sert su uygulamalarında yüksek pigmentli iç cephe boyaları için saklama stabilitesi sağlar ve çalışma aletlerinin temizliğini kolaylaştırır.

20°C'nin altındaki sıcaklıklarda başarılı bir film oluşumu için beyaz ispirto, glikol eterler ve Lusolvan FBH, SolvenonPP gibi birleştiricilerin eklenmesi tavsiye edilir.
Önerilen tüketim yaklaşık %2'dir (toplam hacme göre).

Filmi özellikle esnek hale getirmek için plastikleştiriciler, örneğin Plastilit 3060 veya klorlu parafin veya ftalik asit ester eklenebilir.
ACRONAL TS 790'ın şeffaf bir film oluşumunu destekleyen yumuşak dispersiyonlarla (örn. ACRONAL S 400) karıştırmak da mümkündür.

Saf akrilat veya polivinil ester bazlı dispersiyonlarla karıştırmak da mümkündür ancak şeffaf bir film vermez ve herhangi bir teknik avantaj sunmaz.
ACRONAL TS 790'ın diğer dispersiyonlarla uyumluluğu, stabilize edici koruyucu bir kolloid olan CollacralVAL'ın eklenmesiyle geliştirildi.

Tüm ince dispersiyonlar gibi ACRONAL TS 790 da köpürme eğilimindedir.
Bu nedenle ACRONAL TS 790'ın köpük önleyici maddelerin üreticilerin önerdiği miktarlarda (yaklaşık %0,3 - 1) eklenmesi gerekir.
Köpük kesicilerin etkinliği ampirik olarak belirlenmelidir.

ACRONAL TS 790 mikroorganizmaların saldırılarına karşı korunmasına rağmen, depolama sırasında stabilitelerini sağlamak için nihai ürünlere koruyucular eklenmelidir.
Kullanılan koruyucunun uyumluluğu ve etkinliği her zaman ampirik olarak test edilmelidir.

Üreticiler ACRONAL TS 790'ı kullanarak kendi sıkı ürün geliştirme denemelerini yapmalıdır çünkü denemelerimiz ürün üretimini ve kullanımını etkileyebilecek tüm faktörleri (örn. bileşen uyumluluğu, karıştırma işlemi, çeşitli yüzeylere yapışma vb.) kapsayamaz.
50°C'de saklandıktan sonra viskozite stabilite testleri de yapılmalıdır.

ACRONAL TS 790'ın Saklanması:
ACRONAL TS 790 depolama ve işleme sırasında aşındırıcı metaller veya bunların koruyucu kaplaması olmayan alaşımları ile temas etmemelidir.
Depolama sırasında ürün kapları sıkıca kapatılmalı ve üzerindeki boş hava alanı neme doyurulmalıdır.
ACRONAL TS 790 aşırı sıcağa ve donmaya maruz bırakılmamalıdır.

Mikroorganizmalarla ilgili sorunları önlemek için ürün saklama kaplarında hijyen önlemlerine uyulmalıdır.

ACRONAL TS 790'ın raf ömrü 10 - 30 °C'de saklandığında 6 aydır.

ACRONAL TS 790 Güvenliği:
Kimyasalların kullanımıyla ilgili genel gerekliliklere ve yerel endüstriyel hijyen düzenlemelerine uyulmalıdır.
İşleme sırasında etkili havalandırmanın yanı sıra cilt ve gözlük için kişisel koruyucu ekipmanlar da sağlanmalıdır.

ACRONAL TS 790'ın Özellikleri:
Dispersiyon tipi: anyonik
Katı içeriği: ca. %50
pH değeri: ca. 7,5 – 9,0
Viskozite1: ca. 700–1.500 mPa·s
Ortalama parçacık boyutu: ca. 0,1 µm
MFFT: ca. 20°C
Özgül ağırlık (dağılım): ca. 1,04 g/cm³
Özgül ağırlık (kuru polimer): ca. 1,08 gr/c

Ürün Kümesi:
Dispersiyonlar

Ürün grubu:
Stiren Akrilikler

Endüstri:
Yapı

Kimyasal türü:
Stiren akrilikler

Diğer ACRONAL Ürünler:
ACRONAL S 790
ACRONAL 290 D
ACRONAL T 290 D
ACRONAL S 562
ACRONAL S 562 T
ACRONAL ECO 6716
ACRONAL ECO 6716 T
ACRONAL PLUS 6727
ACRONAL S 813
ACRONAL ECO 6258
ACRONAL EDGE 6283
ACRONAL EDGE 6295
ACRONAL A 684
ACRONAL A 754
ACRONAL TA 754
ACRONAL PLUS 6257
ACRONAL DS
ACRONAL DS 6266
ACRONAL ECO 6270
ACRONAL LR 9014
ACRONAL TX 9014

ACRONAL TS 790, izotiazolinon ailesine ait kimyasal bir bileşiktir.
ACRONAL TS 790 metal işleme sıvısı, Kathon CG'de bulunan iki izotiazolionun %13,9 konsantrasyonda bir karışımıdır.
ACRONAL TS 790, zararlı mikroorganizmaların üremesini engellemeye yardımcı olur.

CAS Numarası: 55965-84-9
Moleküler formül: C4H5NOS. C4H4ClNOS
Moleküler Ağırlık: 264.756
EINECS Numarası: 911-418-6

ACRONAL TS 790 esas olarak metal işleme sıvılarında bulunur.
Aigezid II.'nin aktif bir bileşeni olarak ACRONAL TS 790 ve ftotografik gelişim için kullanılan bir su banyosunda bulunan bir fotoğraf geliştiricisinde kontakt dermatite neden oldu.

ACRONAL TS 790, izotiazolinon türevi biyositlerin bir karışımıdır.
ACRONAL TS 790, %0,0002, 0,0002, 0,00005 ve %0,00005 (w/w) Gram-pozitif ve Gram-negatif bakteri değerlerine karşı etkilidir.
ACRONAL TS 790 kontakt sensitizasyonu ortaya çıkarabilir.

ACRONAL TS 790 içeren formülasyonlar, sanayi ve ev ürünlerinde mikrobiyal büyümenin kontrolünde kullanılmıştır.
ACRONAL TS 790, çeşitli kişisel bakım, ev ve sanayi ürünlerinde kullanılan iki sentetik koruyucunun birleşimidir.
Bu koruyucular, ürünlerde bakteri, mantar ve diğer mikroorganizmaların büyümesini önlemeye yardımcı olan, böylece raf ömrünü uzatan ve kalitelerini koruyan antimikrobiyal ajanlardır.

ACRONAL TS 790T kombinasyonu, karışımın genel antimikrobiyal aktivitesini artıran sinerjik bir etki yaratır.
İki farklı antimikrobiyal ajanı birleştirerek, koruyucu daha geniş bir mikroorganizma yelpazesini hedefleyebilir ve daha kapsamlı koruma sağlayabilir.
ACRONAL TS 790 Kullanım Düzeyleri ve Konsantrasyonları; ürünlerdeki ACRONAL TS 790 konsantrasyonları, kullanım amacına, ürün tipine ve düzenleyici yönergelere bağlı olarak değişebilir.

ACRONAL TS 790 üreticileri, advers reaksiyon potansiyelini en aza indirirken etkili koruma sağlamak için önerilen kullanım seviyelerini takip eder.
ACRONAL TS 790, ürünün bileşenlerini bozabilecek mikroorganizmaların büyümesini önleyerek ürünlerin stabilitesini ve kalitesini korumaya yardımcı olur.
ACRONAL TS 790 içeren ürünlerle ilişkili alerjik kontakt dermatit raporları vardır.

ACRONAL TS 790, düzenleyici eylemlere ve kullanımlarının daha fazla incelenmesine yol açmıştır.
Endişelere yanıt olarak, bazı üreticiler ACRONAL TS 790 kullanımını azaltmak veya ortadan kaldırmak için ürünlerini yeniden formüle etmişlerdir.
ACRONAL TS 790'ın ACRONAL TS 790ted olduğu bölgelerde, yönetmelikler genellikle tüketicileri bilgilendirmek ve hassasiyeti olanların bilinçli seçimler yapmasına izin vermek için bu koruyucuları içeren ürünlerin uygun şekilde etiketlenmesini gerektirir.

Üreticiler, seçilen ACRONAL TS 790 konsantrasyonunun, ürünün raf ömrü boyunca mikrobiyal büyümeyi etkili bir şekilde önlediğinden emin olmak için koruyucu etkinlik testi yapmaktadır.
ACRONAL TS 790'ın güvenliği ve hassaslaştırma potansiyeli hakkındaki tartışmalar, kozmetik ve kişisel bakım endüstrisini alerjik reaksiyon riski daha düşük olan alternatif koruyucuları keşfetmeye teşvik etmiştir.
Doğal koruyucular, antioksidanlar ve diğer sentetik alternatifler potansiyel ikameler olarak araştırılmaktadır.

ACRONAL TS 790 ve MI, çeşitli kişisel bakım ve ev ürünlerinde koruyucu olarak yaygın olarak kullanılan kimyasal bileşiklerdir.
Bunlar, bakterilerin, mayaların ve küflerin büyümesini önleyerek ürünlerin raf ömrünü uzatmak için kullanılan izotiazolinonlar olarak bilinen bir grup kimyasalın bir parçasıdır.

ACRONAL TS 790 antimikrobiyal özelliklere sahiptir ve genellikle şampuanlar, saç kremleri, sıvı sabunlar ve diğer su bazlı kozmetik ve kişisel bakım ürünleri gibi ürünlerde koruyucu olarak kullanılır.
ACRONAL TS 790, ürünün bozulmasına veya kirlenmesine yol açabilecek mikroorganizmaların üremesini önlemeye yardımcı olur.

ACRONAL TS 790, koruyucu olarak yaygın olarak kullanılan başka bir izotiazolinon bileşiğidir.
ACRONAL TS 790, MI ile yakından ilişkilidir ve benzer antimikrobiyal özelliklere sahiptir.
ACRONAL TS 790, kozmetikler, cilt bakım ürünleri, deterjanlar, boyalar ve endüstriyel ürünler dahil olmak üzere geniş bir ürün yelpazesinde kullanılmaktadır.

Hem ACRONAL TS 790 hem de MI, özellikle cilt hassasiyeti ve alerjik reaksiyonlar açısından potansiyel sağlık sorunları ile ilişkilendirilmiştir.
Bazı kişiler bu bileşikleri içeren ürünlere maruz kaldıklarında alerjik kontakt dermatit gelişebilir.

Gözlemlenen sağlık endişeleri nedeniyle, çeşitli ülkelerdeki düzenleyici kurumlar, tüketici ürünlerinde ACRONAL TS 790 ve MI kullanımını düzenlemek için harekete geçmiştir.
Örneğin, Avrupa Birliği'nde, bazı ACRONAL TS 790 ve MI konsantrasyonları, losyonlar ve kremler gibi uygulamadan sonra ciltte kalması amaçlanan ürünler olan kozmetik ürünlerde kısıtlanmıştır.
Bu düzenleme, bildirilen cilt hassaslaşması vakalarına yanıt niteliğindedir.

Birçok ülkede, ACRONAL TS 790 veya MI içeren ürünler, tüketicileri varlıkları hakkında bilgilendirmek için uygun şekilde etiketlenmelidir.
Bu, bilinen hassasiyetleri veya alerjileri olan bireylerin bu bileşikleri içeren ürünlerden kaçınmalarını sağlar.
ACRONAL TS 790 ve MI ile ilişkili potansiyel cilt hassaslaştırma riskleri göz önüne alındığında, birçok üretici ürünlerini alternatif koruyucular kullanacak şekilde yeniden formüle etmeye başlamıştır.

Form: sıvı, dispersiyon
Renk: beyaz
Koku: neredeyse kokusuz
pH değeri: 7,5 - 9,0 (23 °C)
Hakkında bilgi: Su
Erime noktası: 0 °C
Hakkında bilgi: Su
Kaynama noktası: 100 °C
Parlama noktası: uygulanamaz
Yanmazlık: yanıcı değil
Alt patlama liACRONAL TS 790: Sınıflandırma ve etiketleme ile ilgili olmayan sıvılar için.
Hakkında bilgi: Su
Buhar basıncı: 23,4 hPa (20 °C)
Yoğunluk: yaklaşık 1,0 g/cm3 (20 °C)
Suda çözünürlük: kısmen çözünür (15 °C)
Özgül ağırlık (dispersiyon): yaklaşık 1,04 g/cm³
Özgül ağırlık (kuru polimer): yaklaşık 1,08 g/cm³

ACRONAL TS 790, hücre sızıntısına ve ölümüne yol açan mikroorganizmaların hücre zarlarını bozarak çalışır.
Bu etki şekli, bakteri ve mantarların büyümesini ve çoğalmasını engeller.
ACRONAL TS 790, kişisel bakım, ev ve endüstriyel ürünlerde bulunan yaygın olarak kullanılan bir antimikrobiyal koruyucu kombinasyondur.

ACRONAL TS 790 mikrobiyal kontaminasyonun önlenmesine, raf ömrünün uzatılmasına ve çeşitli formülasyonların kalitesinin korunmasına yardımcı olur.
ACRONAL TS 790 hem mikrobiyostatik bir ajan (mikrobiyal büyümeyi inhibe eden) hem de bir mikrobisidal ajan (mevcut mikroorganizmaları öldüren) olarak işlev görür.
Bu ikili eylem, ürünlerin bütünlüğünün korunmasına yardımcı olur.

ACRONAL TS 790 mikrobiyal büyümeyi etkili bir şekilde önlerken, bazı kişilerde alerjik reaksiyon potansiyeli nedeniyle kullanımı zor olabilir.
Endüstri, hassaslaştırma sorunlarına neden olmadan mikrobiyal korumanın faydalarını koruyan alternatifler bulma baskısıyla karşı karşıya kalmıştır.
Üreticiler bazen daha geniş bir antimikrobiyal aktivite spektrumu elde etmek ve her bir koruyucunun konsantrasyonunu azaltmak için ACRONAL TS 790'ı diğer koruyucularla birlikte kullanırlar.

ACRONAL TS 790'ın ürün formülasyonlarındaki diğer bileşenlerle uyumluluğu, nihai ürünün genel stabilitesini ve etkinliğini korumak için önemlidir.
Düzenleyici makamlar, bildirilen alerjik kontakt dermatit vakaları nedeniyle ACRONAL TS 790 kullanımı için kısıtlamalar ve kılavuzlar getirmiştir.
Bazı durumlarda, belirli ürün kategorileri veya ACRONAL TS 790 konsantrasyonları yasaklanmıştır.

Yama testi, bir bireyin ACRONAL TS 790'a duyarlılığını veya alerjisini belirlemek için kullanılır ve advers reaksiyonların potansiyel risklerini belirlemeye yardımcı olur.
Ürünlerde ACRONAL TS 790'ın varlığı ve yama testinin önemi hakkında tüketici bilincinin arttırılması, bireylerin bilinçli seçimler yapmalarını sağlayabilir.
Bebekler, çocuklar ve hassas veya tehlikeye atılmış cilde sahip bireyler gibi bazı popülasyonlar, ACRONAL TS 790 içeren ürünlerden kaynaklanan reaksiyonlara karşı daha duyarlı olabilir.

ACRONAL TS 790'a karşı hassaslaşma potansiyeli, üründeki konsantrasyon, maruz kalma sıklığı, bireysel cilt hassasiyeti ve diğer alerjenlerin varlığı gibi faktörlerden etkilenebilir.
Dermatologlar ve alerjistler, ACRONAL TS 790 dahil olmak üzere spesifik alerjenlere duyarlılığı tanımlamak için yama testi kullanırlar.
Bu, bireylerin ürün kullanımı hakkında bilinçli seçimler yapmasına yardımcı olur.

Hassaslaşmaya eğilimli bazı kişiler, alerji geliştirme riskini en aza indirmek için farklı koruyuculara sahip ürünler kullanarak koruyucu bir rotasyon stratejisi izleyebilir.
ACRONAL TS 790'ın çocuklara yönelik ürünlerde kullanılması, genç ve hassas ciltlerde hassaslaşma potansiyeli nedeniyle endişelere yol açmıştır.
Bu ürünler için düzenlemeler ve yönergeler farklılık gösterebilir.

Kullanımlar
ACRONAL TS 790 Kozmetiklerde, hijyen ürünlerde, boyalarda, emülsiyonlarda, kesme yağlarında, kağıt kaplamalarda, su depolama ve soğutma ünitelerinde antimikrobiyal koruyucuda kullanılır.
ACRONAL TS 790, çeşitli ürünlerde koruyucu olarak kullanılan kimyasal bir bileşiktir.
ACRONAL TS 790, bakteri ve mantarlara karşı geniş spektrumlu antimikrobiyal aktiviteye sahiptir.

ACRONAL TS 790'lar, suyun varlığının mikrobiyal büyümeye elverişli bir ortam yaratabileceği su bazlı ürünlerde özellikle etkilidir.
ACRONAL TS 790 ve MI, soğutma kuleleri ve endüstriyel su kaynakları gibi su sistemlerinde mikroorganizmaların büyümesini engellemek için su arıtımında kullanılabilir.
ACRONAL TS 790, bazı tekstil ve kumaş işlemlerinde koku veya bozulmaya neden olabilecek mikroorganizmaların üremesini önlemek için kullanılır.

ACRONAL TS 790, şampuanlar, saç kremleri, vücut yıkamaları, losyonlar, kremler ve kozmetikler gibi kişisel bakım ürünlerinde yaygın olarak bulunur.
Bakteri, maya ve mantarların büyümesini önleyerek ürün hijyeni ve kalitesinin korunmasına yardımcı olur.
ACRONAL TS 790, deterjanlar, yumuşatıcılar, dezenfektanlar ve yüzey temizleyicileri gibi ev temizlik ürünlerinde mikrobiyal büyümeyi engellemek ve ürün etkinliğini korumak için kullanılır.

ACRONAL TS 790, mikroorganizmaların neden olduğu bozulmayı önlemek için boyalar, yapıştırıcılar ve kaplamalar dahil olmak üzere endüstriyel formülasyonlarda kullanılır.
ACRONAL TS 790'lar, sıvı sabunlar, vücut yıkamaları ve şampuanlar gibi mikrobiyal kontaminasyonun endişe verici olduğu su bazlı ürünlerde kullanılır.
ACRONAL TS 790, tazeliğini ve mikrobiyal güvenliğini sağlamak için ıslak mendillere dahil edilmiştir.

ACRONAL TS 790 ve MI, kalitelerini ve güvenliklerini korumak için şampuanlar ve bakım malzemeleri gibi bazı evcil hayvan bakım ürünlerinde bulunabilir.
Araba yıkama çözümleri ve iç temizleyiciler de dahil olmak üzere bazı otomotiv ürünleri, mikrobiyal büyümeyi önlemek ve ürün etkinliğini korumak için ACRONAL TS 790 ve MI içerebilir.
Bazı durumlarda, ACRONAL TS 790 ve MI, mikrobiyal kontrolün gerekli olduğu tıbbi ve sağlık ortamlarında kullanılır.

Bazı dezenfektan türlerinde, tıbbi cihaz temizleyicilerinde ve el dezenfektanlarında bulunabilirler.
ACRONAL TS 790 ve MI bazen mikrobiyal kontaminasyonu önlemek ve bu ürünlerin stabilitesini korumak için fotografik kimyasallarda kullanılır.
Metal işleme gibi endüstriyel proseslerde, işleme operasyonlarını etkileyebilecek mikroorganizmaların büyümesini engellemek için kesme sıvılarına ve soğutma sıvılarına ACRONAL TS 790 ve MI eklenebilir.

ACRONAL TS 790 ve MI, yüzeyleri dezenfekte etmek ve sterilize etmek amacıyla kullanılan temizlik mendilleri ve havlularda bulunabilir.
Kişisel bakım ve temizlik de dahil olmak üzere çeşitli uygulamalardaki ıslak mendiller, nemli ortamda bakteri ve mantar üremesini önlemek için ACRONAL TS 790 ve MI içerebilir.
KRONAL TS 790 ve MI, bazı su bazlı boya ve kaplamalarda bozulmayı önlemek ve ürün kalitesini korumak için kullanılır.

ACRONAL TS 790'lar, ürün stabilitesini ve kalitesini korumak için makyaj temizleyicileri, yüz temizleyicileri ve nemlendiriciler gibi kozmetiklerde kullanılır.
ACRONAL TS 790, saç kremi ve saç şekillendirme ürünleri gibi saç bakım ürünlerinde mikroorganizmaların üremesini önlemeye yardımcı olur.
Kesme sıvıları ve metal işleme sıvıları gibi çeşitli endüstriyel ürünlerde, ACRONAL TS 790 mikrobiyal büyümeyi engelleyerek ürün performansının korunmasına katkıda bulunur.

ACRONAL TS 790, kumaşlarda kokuya neden olan bakteri ve mantarların üremesini önlemek için çamaşır deterjanlarında bulunabilir.
ACRONAL TS 790'lar otomotiv ve endüstriyel temizlik ürünlerinde mikrobiyal kontaminasyondan uzak kalmalarını sağlamak için kullanılır.
ACRONAL TS 790, yapıştırıcılarda ve sızdırmazlık maddelerinde, ürünlerin bütünlüğünü tehlikeye atabilecek mikrobiyal büyümeyi önlemek için kullanılır.

ACRONAL TS 790'lar bazı kağıt ürünlerinde küf ve diğer mikroorganizmaların büyümesini önlemek için kullanılır.
ACRONAL TS 790, ACRONAL TS 790T ile kombinasyon halinde sıklıkla kullanılan başka bir antimikrobiyal bileşiktir.
Çok çeşitli mikroorganizmalara karşı ek antimikrobiyal koruma sağlar.

ACRONAL TS 790, şampuanlar, saç kremleri, vücut yıkamaları, losyonlar, kremler ve kozmetikler dahil olmak üzere çeşitli kişisel bakım ürünlerinde yaygın olarak bulunur.
Varlığı, bu ürünlerdeki mikroorganizmaların büyümesini önlemeye yardımcı olur ve kontaminasyon riskini azaltır.

ACRONAL TS 790, deterjanlar, yumuşatıcılar ve temizlik solüsyonları gibi ev ürünlerinde mikrobiyal büyümeyi engelleyerek ürün kalitesini ve güvenliğini korumak için kullanılır.
ACRONAL TS 790, boyalar, yapıştırıcılar ve endüstriyel temizleyiciler dahil olmak üzere çeşitli formülasyonlarda mikroorganizmaların çoğalmasını önlediği endüstriyel ortamlarda da kullanılır.

Çevresel Hususlar
Diğer sentetik kimyasallar gibi, ACRONAL TS 790 da atık su gibi çevreye salındığında çevresel etkileri hakkında endişelerini dile getirmiştir.
Endüstri çabaları daha çevre dostu koruyucular ve sürdürülebilir uygulamalar geliştirmeye yönlendirilmektedir.

Emniyet
ACRONAL TS 790 ve MI'nin en önemli tehlikelerinden biri, cilt hassasiyetine neden olma potansiyelleridir.
Cilt hassaslaşması, bağışıklık sistemi belirli bir maddeye duyarlı hale geldiğinde ortaya çıkan ve daha sonra maruz kalındığında alerjik bir yanıtın gelişmesine neden olan alerjik bir reaksiyondur.
ACRONAL TS 790 ve MI'ye duyarlı hale gelen kişilerde kızarıklık, kaşıntı, döküntü ve diğer cilt tahrişleri olarak kendini gösteren kontakt dermatit gelişebilir.

Alerjik Reaksiyonlar
ACRONAL TS 790 ve MI'ye duyarlı olan bireyler, düşük konsantrasyonlarda bile maruz kaldıklarında alerjik reaksiyonlar yaşayabilirler.
Alerjik reaksiyonlar şiddete göre değişebilir ve etkilenen bireyler için rahatsızlık, ağrı ve yaşam kalitesinin düşmesine neden olabilir.

Eş Anlamlılar
55965-84-9
KRONAL TS 790
Kathon biyosit
Kathon CG
Bio-Perge
Kathon LX
Kathon WT
Zonen F
ProClin 300 Serisi
Mikrosit III
Somacide RS
Efsane MK
KRONAL TS 790MW
Kathon CG/ICP II
Slaoff 360 ·
KRONAL TS 790 W
Kathon RH 886 ·
MBC 215 Serisi
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KKM 43
İzotiazolinon klorür
EPA Pestisit Kimyasal Kodu 107103
5-kloro-2-metil-1,2-tiazol-3-bir;2-metil-1,2-tiazol-3-one
5-Kloro-2-metil-3 (2H)-izotiazolon karışımı. 2-metil-3 (2H)-izotiazolon ile
2-Metilizotiyazol-3 (2H)-5-kloro-2-metilizotiazol-3 (2H)-bir (1: 1) ile bir bileşik
3 (2H)-İzotiazolon, 5-kloro-2-metil-, karıştırın. 2-metil-3 (2H)-izotiazolon ile
3 (2H)-İzotiazolon, 5-kloro-2-metil-, karıştırın. ile2-metil-3 (2H)-izotiazolonDİĞER CA İNDEKS İSİMLERİ:3(2H)-İzotiyazolon, 2-metil-, karışım. devamı.
C8H9ClN2O2S2
2-Metilizotiyazol-3 (2H)-bir 5-kloro-2-metilizotiyazol-3 (2H)-bir (1:1)
C4H5NOS. C4H4ClNOS
SCHEMBL348332
UNII-15O9QS218W
CHEMBL108095
KRONAL TS 790 (Kathon Biyosit)
C(M)IT/KISALTMA TS 790 (3:1)
QYYMDNHUJFIDDQ-UHFFFAOYSA-N
15O9QS218W
AKOS016842708
CS-W018768
70294-89-2
CS-17384
LS-86321
PD151064
C4-H5-N-O-S. C4-H4-Cl-N-O-S
26841195. Çeyrek
2-Metilizotiyazol-3 (2H)-bir 5-kloro-2-Metilizotiyazol-3 (2H)-bir
2-Metilizotiyazol-3 (2H)-bir 5-kloro-2-metilizotiazol-3 (2H)-bir (1: 1) suda% 14
2-Metilizotiyazol-3 (2H)-5-kloro-2-metilizotiazol-3 (2H)-bir bileşik
2-Metilizotiyazol-3 (2H)-onebileşik5-kloro-2-metilizotiyazol-3 (2H)-bir (% 14 inH2O)
2-METILIZOTIYAZOL-3 (2H)-BIR BILEŞIK 5-KLORO-2-METILIZOTIYAZOL-3 (2H)-BIR (H2O'DA% 14)

ACRONAL V 275 ACRONAL V 275 ACRONAL V 275, zemin yapıştırıcılarında ve özel sızdırmazlıklarda kullanılan yüksek katılı bir akrilik bağlayıcıdır. ACRONAL V 275 amonyak içermez ve yüksek kohezif mukavemet, iyi plastikleştirici direnci ve dolgu kabulü sunar. Kısaltma V 275 Teknik veri sayfası Acronal V 275, bir akrilik / vinil asetat kopolimer emülsiyonudur. PVC zemin kaplamalarının ve birçok farklı arkalık ve özel dolgu macunu ile halıların döşenmesi için yapıştırıcılarda kullanılır. Acronal V 275 na yüksek yapışma, iyi hızlı kavrama, ısı stabilitesi, iyi plastikleştirici migrasyon direnci ve iyi dolgu kabulü sunar. Ürün Tipi Akrilikler ve Akrilik Kopolimerler Fiziksel Form Emülsiyonu Ürün Durumu TİCARİ Acronal V 275 na, zemin yapıştırıcılarında ve özel sızdırmazlık maddelerinde kullanılan yüksek katı içerikli bir akriliktir. Yüksek yapışma mukavemeti, iyi plastikleştirici direnci ve dolgu kabulü sunar. Bu ürün amonyak içermez. Teknik Bilgiler Yapı Kimyasalları Kısaltma V 275 İnşaat endüstrisi için yapıştırıcı ve sızdırmazlık malzemesi üretimi için sulu polimer dispersiyonu. Acronal 81 D, akrilik bir dispersiyondur. Elastik mastiklerde boşluk dolgusu olarak kullanılır. Acronal® 81 D, genleşebilir köpüklerin tutarlılığını geliştirir.

SYNONYMS 2-Propenamide, polymer with N,N,N-trimethyl-3-(2-propenamido)propanaminium chloride;1-Propanaminium, N,N,N-trimethyl-3-((1-oxo-2-propen-1-yl)amino)-, chloride (1:1), polymer with 2-propenamide;1-Propanaminium, N,N,N-trimethyl-3-((1-oxo-2-propenyl)amino)-, chloride, polymer with 2-propenamide CAS NO:75150-29-7

acrylamide; Acrylic amide; Ethylene Carboxamide; 2-Propenamide; Propenoic acid, amide; Vinyl Amide; cas no: 79-06-1

Poly(acrylamide-co-sodium acrylate); Sodium acrylate-acrylamide copolymer; Sodium polyacrylate-acrylamide resin; Sodium acrylate, polymer with acrylamide; 2-Propenoic acid, sodium salt, 2-propenamide polymer CAS NO:25987-30-8

Ethylic acid; Methanecarboxylic acid; vinegar; Vinegar acid; Acetic acid, glacial; Essigsäure; ácido acético; Acide acétique; Ethanoic acid; Acetasol; Octowy kwas; Kyselina octova; Essigsaeure; Octowy kwas; Vosol; CHLORINE IODIDE; CHLOROIODIDE; IODINE CHLORIDE; IODINE MONOCHLORIDE; IODINE MONOCHLORIDE SOLUTION, WIJS; IODINE-MONOCHLORIDE, WIJS; IODINE SOLUTION ACCORDING TO WIJS; IODOCHLORIDE; IODOMONOCHLORIDE; WIJS CHLORIDE; WIJS' CHLORIDE; WIJS IODINE SOLUTION; WIJ'S IODINE SOLUTION; WIJS REAGENT; WIJS' REAGENT; WIJS SOLUTION; WIJS' SOLUTION; Acetasol; aceticacid(non-specificname); aceticacid(solutionsgreaterthan10%) CAS NO:64-19-7, 77671-22-8

BUTYL ACRYLATE, N° CAS : 141-32-2, Nom INCI : BUTYL ACRYLATE, Nom chimique : 2-Propenoic acid, butyl ester, N° EINECS/ELINCS : 216-768-7 (I). Agent fixant : Permet la cohésion de différents ingrédients cosmétiques. Principaux synonymes. Noms français : 2-PROPENOIC ACID, BUTYL ESTER; Acrylate de butyle;Acrylate de butyle normal; ACRYLATE DE N-BUTYLE BUTYL 2-PROPENOATE; BUTYL ACRYLATE (NORMAL-); PROPENOATE-2 DE BUTYLE; PROPENOATE-2 DE BUTYLE NORMAL; PROPENOATE-2 DE N-BUTYLE. Noms anglais : ACRYLIC ACID, BUTYL ESTER; Butyl acrylate; n-Butyl acrylate; NORMAL BUTYL ACRYLATE. Commentaires: L'acrylate de butyle normal contient généralement un inhibiteur de polymérisation, l'éther monométhylique de l'hydroquinone (entre 10 et 20 ppm). La présence d'oxygène dissout étant essentielle àl'efficacité de l'inhibiteur, il ne doit pas être entreposé sous atmosphère inerte. Utilisation: L'acrylate de butyle normal sert presqu'exclusivement àla production de polymères, la grande majorité étant des copolymères. Ces derniers peuvent servir àla fabrication de divers revêtements, élastomères, adhésifs, agents de surface, plastiques, textiles et encres. Ils sont également utilisés dans la fabrication de matériaux superabsorbants et de détergents. 2-Propenoic acid, butyl ester Acrylic acid butyl ester (8CI) Acrylic acid n-butyl ester Acrylic acid, butyl ester acrylic acid, n-butyl ester Butyl 2-propenoate Butyl acrylate BUTYL ACRYLATES, STABILIZED Butylester kyseliny akrylove n-Butyl acrylate n-Butyl propenoate n-Butylacrylate acrilato de n-butilo (es) acrilato di n-butile (it) acrylate de n-butyle (fr) akrylan butylu (pl) butil-akrilát (hu) butilakrilatas (lt) butyl-akrylát (cs) butylacrylat (da) butylakrylat (sv) ester butylowy kwasu akrylowego (pl) n-butil acrilate (ro) n-butil akrilat (sl) n-butil-akrilat (hr) n-butilacrilato (it) n-butilakrilāts (lv) n-butylacrylaat (nl) n-Butylacrylat (de) n-butylakrylat (no) n-Butyyliakrylaatti (fi) n-butüülakrülaat (et) n-бутил акрилат (bg) ακρυλικός n-βουτυλεστέρας (el) 2-Propenoic acid, n-butyl ester ABU Acrylic acid butyl ester; n-Butyl acrylate; Acrylic acid, n-butyl ester; 2-Propenoic acid, butyl ester; Butyl 2-propenoate; n-Butyl propenoate; Butylacrylate, inhibited; Butyl ester kyseliny akrylove; UN 2348 butyl acrilate Butyl acryate butyl acrylate (BA) Butyl Acrylate (stabilized with MEHQ) Butyl prop-2-enoate butyl propenoate butylacrylate butyll prop-2-enoate n Butyl acrylate monomer s 2-Propenoic acid, butyl ester (9CI) Acrylic acid butyl ester (6CI, 8CI) Acrylic acid n-butyl ester, Butyl 2-propeonate ACRYLIC ACID NORMAL-BUTYL ESTER Acrylsaeurebutylester BA Butyl Acrylate ; Acrylic acid butyl ester Butyl Acylate Butyl Acylate Monomer Butyl ester acrylic acid FLOWING AGENT TP88 n-butyl acetate N-BUTYL-2-PROPENOATE TP88 UN 2348 ZMATLTXT

SYNONYMS Ethylic acid; Methanecarboxylic acid; vinegar; Vinegar acid; Acetic acid, glacial; CAS NO. 64-19-7, 77671-22-8

SYNONYMS 2-propenoic acid, 2-methyl-, polymer with ethyl 2-propenoate and methyl 2-methyl-2-propenoate CAS NO: 25133-97-5

C10-30 alkyl propenoate, polymer with propenoic acid, butenoic acid and/or alkyl propenoates, product with propenyl sucrose ether or propenyl 2,2-dihydroxymethyl-1,3-propanediol cas: 110-82-7

Acroleic acid; 2-Propenoic acid; Acrylate; Ethylenecarboxylic acid; propene acid; Propenoic acid; Vinylformic Acid; Acide acrylique; Acido acrilio; Kyselina akrylova; 2-PROPENOIC ACID; Acroleic acid; ACRYLIC ACID; AKOS BBS-00003787; ETHYLENECARBOXYLIC ACID; PROPENOIC ACID; RARECHEM AL BO 0141; 2-Propensαure; acideacrylique; acideacrylique(french); acidoacrilio; Acrylate; acrylicacid,[waste]; acrylicacid,glacial; acrylicacid,inhibited; Acrylsαure; ai3-15717; caswellno.009a; CH2=CHCOOH; Glacial acrylic acid CAS NO: 79-10-7

2-Propenoic acid, 2-methyl-, 2-methylpropylester, polymer with 2-propenoic acid and N-(1,1,3,3-tetramethylbutyl)-2-propenamide CAS No:129702-02-9

Acrylic acid-acrylate polymer; Acrylates copolymer,Copolymer acrylate; acrylic acid terpolymer, partial sodium salts;methyl methacrylate/ ethyl acrylate/ methacrylic acid pol.; Ethyl acrylate·methacrylic acid·methyl methacrylate copolymer; polymer with ethyl 2-propenoate and methyl 2-methyl-2-propenoate; ethyl prop-2-enoate,methyl 2-methylprop-2-enoate,2-methylprop-2-enoic acid; 2-Propenoic acid, 2-methyl-, polymer with ethyl 2-propenoate and methyl 2-methyl-2-propenoate CAS No:25133-97-5