ACETOACETANILIDE (3-OXO-N-PHENYL BUTANAMIDE)

ACETOACETANILIDE
PRODUCT IDENTIFICATION
CAS NO.	102-01-2
EINECS NO.	202-996-4
FORMULA	CH₃COCH₂CONHC₆H₅
MOL WT.	177.2
H.S. CODE	2924.29
CLASSIFICATION	ACETOACETIC ACID DERIVATIVES / AMIDES /
TOXICITY	Oral, rat LD50: 5000 mg/kg
SYNONYMS	3-Oxo-n-Phenyl Butanamide; Acetylacetanilide;
Acetoaceticanilide; ((Acetoacetyl)Amino)Benzene; Beta-ketobutyranilide; N-Phenylacetoacetamide; N-phenyl-3-oxobutanamide; Acetessigsäureanilid (German); Acétoacétanilide(French); Acetoacetanilide(Italian); AAA; AAN;
SMILES
PHYSICAL AND CHEMICAL PROPERTIES
PHYSICAL STATE	White or Light Yellow Solid
MELTING POINT	85 C
BOILING POINT
SPECIFIC GRAVITY	1.26
SOLUBILITY IN WATER	5.0 g/l (soluble in dilute sodium hydroxide, alcohol, ether, acids, chloroform, and hot benzene)
pH
VAPOR DENSITY
AUTOIGNITION
NFPA RATINGS
REFRACTIVE INDEX
FLASH POINT	162 C
STABILITY	Stable under ordinary conditions
APPLICATIONS
Acetoacetanilide is used in manufacturing agricultural chemicals, coating materials, dyes and pigments ( the dry colors generally referred to as Hansa and benzidine yellows) as well as a co-promoters for unsaturated polyesters. Diketene derivativesa (mainly cetoacetic acid derivatives and heterocycles) have versatile applications including making agrochemicals, dyes, pigments, pharmaceuticals including vitamins, and stabilizers for PVC and polyester. Acetoacetic acid and its esters contain active methylene groups which have relatively acidic alpha-protons due to H atoms adjacent to two carbonyl groups. The reactivity of its methylene group provide the sequence of reactions of alkylation, hydrolysis of the esters and decarboxylation resulting in substituted ketones. Acetoacetic acid derivatives are important aliphatic parts adjoining azo dyes.
SALES SPECIFICATION
APPEARANCE	White to Off-White Powder
ASSAY	99.0% min
WATER	0.2% max
MELTING POINT	83 C min
TRANSPORTATION
PACKING	25kgs in Bag
HAZARD CLASS
UN NO.
GENERAL DESCRIPTION OF AMIDE AND ANILIDE
Amide is a group of organic chemicals with the general formula RCO-NH₂ in which a carbon atom is attached to oxygen in solid bond and also attached to an hydroxyl group, where 'R' groups range from hydrogen to various linear and ring structures or a compound with a metal replacing hydrogen in ammonia such as sodium amide, NaNH₂. Amides are divided into subclasses according to the number of substituents on nitrogen. The primary amide is formed from by replacement of the carboxylic hydroxyl group by the NH2, amino group. An example is acetamide (acetic acid + amide). Amide is obtained by reaction of an acid chloride, acid anhydride, or ester with an amine. Amides are named with adding '-ic acid' or '-oic acid' from the name of the parent carboxylic acid and replacing it with the suffix 'amide'. Amide can be formed from ammonia (NH₃). The secondary and tertiary amides are the compounds which one or both hydrogens in primary amides are replaced by other groups. The names of secondary and tertiary amides are denoted by the replaced groups with the prefix capital N (meaning nitrogen) prior to the names of parent amides. Low molecular weight amides are soluble in water due to the formation of hydrogen bonds. primary amides have higher melting and boiling points than secondary and tertiary amides. Anilide is an amide derived from aniline by substitution of an acyl group for the hydrogen of NH₂. Acetanilide is from acetic acid and aniline. Acetanilide is an odourless, white flake solid or crystalline powder (pure form); soluble in hot water alcohol, ether, chloroform, acetone, glycerol, and benzene;; melting point 114 C and boiling point 304 C; can undergo self-ignite at 545 C, but is otherwise stable under most conditions. Acetanilide which can be obtained by acetylation of aniline undergoes nitration at low temperature and yields highly the para-nitro products. Acetyl group can then be removed by acid-catalyzed hydrolysis to yield para-nitroaniline. Although the activating affection of the amino group can be reduced, the acetyl derivative remains an ortho/para-orientation and activating substituent. Examples of aromatic anilide are benzanilide, C₆H₅NHCOC₆H₅ or Carbanilide (N,N'-diphenylcarbamide). Some structural amides are; Acetamides Acrylamides Anilides Benzamides Naphthylamides Formamides Lactams Salicylamides Sulfonamides Thioamides Fatty amides An amide is hydrolyzed to yield an amine and a carboxylic acid under strong acidic conditions. The reverse of this process resulting in the loss of water to link amino acids is wide in nature to form proteins, the principal constituents of the protoplasm of all cells. Acyl halides are the most reactive but amides the least reactive among carboxylic acid derivatives, as in order of "acyl halides > anhydrides > esters �� acids > amides". In homogeneous solvent systems, amides react with water only in the presence of strong acid or base catalysts under heating. Because of the nitrogen non-bonded electron pair with the carbonyl group, amides are very polar and the basicity is weaker than amines. Electrophiles bond to oxygen atom in preference to the nitrogen in an amide. One example of this reaction is the production of nitriles by dehydration of primary amides when treated with thionyl chloride. The addition of water to nitriles (carbon-nitrogen triple bond) gives an amide. Sulfonamides are analogs of amides in which the atom attached to oxygen in solid bond is sulfur rather than carbon. Sulfonamides react with alkyl halides, acid halides, sulfonyl halides, epihalohydrins, ketones and aldehydes under basic conditions. Benzamide, the simplest aromatic carboxylic amide, is used in the synthesis of various organic compounds. Polyamide is a polymer containing repeated amide groups such as various kinds of nylon and polyacrylamides.
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