541-35-5

Basic information

• Product Name: Butyramide
• Synonyms: Butyrylamide;n-Butylamide;n-Butyrylamide;n-C3H7C(O)NH2;BUTANAMIDE;BUTYRAMIDE;AMIDE C4;N-BUTYRAMIDE
• CAS NO: 541-35-5
• Molecular Formula: C₄H₉NO
• Molecular Weight: 87.12
• EINECS: 208-776-4
• Mol File: 541-35-5.mol
• Article Data: 104

Chemical Properties

• Melting Point: 114-116 °C
• Boiling Point: 216 °C
• Flash Point: 216°C
• Appearance: Colorless to white crystalline powder or flakes
• Density: 1.03
• Vapor Pressure: 0.143mmHg at 25°C
• Refractive Index: 1.4560
• Storage Temp.: Store below +30°C.
• Solubility: alcohol: soluble(lit.)
• PKA: 16.67±0.40(Predicted)
• Water Solubility: soluble
• Merck: 14,1592
• BRN: 1361528
• CAS DataBase Reference: Butyramide(CAS DataBase Reference)
• NIST Chemistry Reference: Butyramide(541-35-5)
• EPA Substance Registry System: Butyramide(541-35-5)

Safety Data

• Hazard Codes: Xn
• Statements: 22
• Safety Statements: 24/25
• WGK Germany: 3
• TSCA: Yes
• Hazardous Substances Data: 541-35-5(Hazardous Substances Data)

Usage

Description

Butyramide, also known as butanamide, is a monocarboxylic acid amide obtained by formal condensation of butanoic acid and ammonia. It is a colorless to white crystalline powder or flakes with a yellowish solid form and a nutty aroma. Butyramide has an aroma threshold value that falls under the nutty type odor category.

Uses

Used in Chemical Synthesis:
Butyramide is used as a key intermediate in the synthesis of various compounds, including hydroxamic acids, electrorheological fluids, and β-amodoorganotin compounds. Its versatile chemical properties make it a valuable component in the development of these materials.
Used in Enzyme Research:
Butyramide serves as a substrate for (+)-γ-lactamase, an enzyme that is crucial in the study of enzyme stability, activity, kinetics, and substrate specificity. By using butyramide as a substrate, researchers can develop microreactors to better understand the behavior and characteristics of (+)-γ-lactamase, which can be applied in various biotechnological and pharmaceutical applications.

InChI:InChI=1/C4H9NO/c1-2-3-4(5)6/h2-3H2,1H3,(H2,5,6)

Upstream product

• 109-74-0 propyl cyanide 
• 105-66-8 propyl butanoate 
• 2208-08-4 ethyl butyrimidate hydrochloride 
• 598-94-7 1,1-Dimethylurea 
• 107-92-6 butyric acid 
• 333-20-0 potassium thioacyanate 
• 187737-37-7 propene 
• 77287-34-4 formamide 
• 67-56-1 methanol 
• 22534-71-0 N-acetyl-butyramide 
• 20730-03-4 butyric acid N'-phenyl-hydrazide 
• 7664-41-7 ammonia 
• 105-54-4 butanoic acid ethyl ester 
• 539-90-2 isobutyl n-butyrate 

Downstream Products

• 114097-59-5 butyryl-(2-methyl-butyryl)-amine 
• 107-87-9 2-Pentanone 
• 107-10-8 propylamine 
• 16536-93-9 butanethioamide 
• 109-74-0 propyl cyanide 
• 71-36-3 butan-1-ol 
• 642-04-6 2,3,5,6-tetraphenylpyrazine 
• 82162-83-2 1-butyryl-3-phenylurea 
• 1129-50-6 N-phenylbutyramide 
• 163685-98-1 N-phenylbutyrimidamide 
• 52414-87-6 4-Methyl-2-propyl-thiazol 
• 53833-32-2 4,5-dimethyl-2-propyl-oxazole 
• 14819-39-7 ethyl 2-propylthiazole-4-carboxylate 
• 141177-98-2 5-Acetyl-3-benzyl-6-propyl-1H-pyrimidine-2,4-dione 

Relevant articles and documents

Nitrogen Atom Transfer Catalysis by Metallonitrene C?H Insertion: Photocatalytic Amidation of Aldehydes

C?H amination and amidation by catalytic nitrene transfer are well-established and typically proceed via electrophilic attack of nitrenoid intermediates. In contrast, the insertion of (formal) terminal nitride ligands into C?H bonds is much less developed and catalytic nitrogen atom transfer remains unknown. We here report the synthesis of a formal terminal nitride complex of palladium. Photocrystallographic, magnetic, and computational characterization support the assignment as an authentic metallonitrene (Pd?N) with a diradical nitrogen ligand that is singly bonded to PdII. Despite the subvalent nitrene character, selective C?H insertion with aldehydes follows nucleophilic selectivity. Transamidation of the benzamide product is enabled by reaction with N3SiMe3. Based on these results, a photocatalytic protocol for aldehyde C?H trimethylsilylamidation was developed that exhibits inverted, nucleophilic selectivity as compared to typical nitrene transfer catalysis. This first example of catalytic C?H nitrogen atom transfer offers facile access to primary amides after deprotection.

Efficient heterogeneous hydroaminocarbonylation of olefins with ammonium chloride as amino source

An efficient protocol for heterogeneous hydroaminocarbonylation of olefins with ammonium chloride without addition of acid additive has been developed for the first time. We successfully synthesized the Pd@POPs-PPh3 catalyst through a solvothermal synthetic method. Under this heterogeneous catalytic system, C2-C6 olefins displayed good yields and TON, and a yield of 66% of propionamide and TON = 1400 were obtained under mild reaction conditions (403 K, Pethylene = 0.5 MPa, PCO = 2.5 MPa), which is a little higher than those in the homogeneous system. This catalytic system has the advantage of easy separation of product and catalyst, as well as good stability. Uniform dispersion of Pd active sites, strong coordination bond between P and Pd, high surface area, large pore volume and hierarchical porosity of Pd@POPs-PPh3 were confirmed by a series of characterizations, which is believed to be the keys for the good activity and stability of hydroaminocarbonylation reaction.

Arene-ruthenium(II)-phosphine complexes: Green catalysts for hydration of nitriles under mild conditions

Three new arene-ruthenium(II) complexes were prepared by treating [{RuCl(μ-Cl)(η6-arene)}2] (η6-arene = p-cymene) dimer with tri(2-furyl)phosphine (PFu3) and 1,3,5-triaza-7-phosphaadamantane (PTA), respectively to obtain [RuCl2(η6-arene)PFu3] [Ru]-1, [RuCl(η6-arene)(PFu3)(PTA)]BF4 [Ru]-2 and [RuCl(η6-arene)(PFu3)2]BF4 [Ru]-3. All the complexes were structurally identified using analytical and spectroscopic methods including single-crystal X-ray studies. The effectiveness of resulting complexes as potential homogeneous catalysts for selective hydration of different nitriles into corresponding amides in aqueous medium and air atmosphere was explored. There was a remarkable difference in catalytic activity of the catalysts depending on the nature and number of phosphorus-donor ligands and sites available for catalysis. Experimental studies performed using structural analogues of efficient catalyst concluded a structural-activity relationship for the higher catalytic activity of [Ru]-1, being able to convert huge variety of aromatic, heteroaromatic and aliphatic nitriles. The use of eco-friendly water as a solvent, open atmosphere and avoidance of any organic solvent during the catalytic reactions prove the reported process to be truly green and sustainable.