4360-47-8

Basic information

• Product Name: CINNAMONITRILE
• Synonyms: 3-phenyl-2-propenenitril;3-phenyl-2-Propenenitrile;beta-cyanostyrene;beta-phenylacrylonitrile;AKOS B004065;3-PHENYLACRYLONITRILE;CINNAMYL NITRILE;CINNAMIC ACID NITRILE
• CAS NO: 4360-47-8
• Molecular Formula: C₉H₇N
• Molecular Weight: 129.16
• EINECS: 217-552-5
• Product Categories: Pharmaceutical Intermediates
• Mol File: 4360-47-8.mol

Chemical Properties

• Melting Point: 18-20 °C(lit.)
• Boiling Point: 254-255 °C(lit.)
• Flash Point: >230 °F
• Appearance: /
• Density: 1.028 g/mL at 25 °C(lit.)
• Vapor Pressure: 0.0101mmHg at 25°C
• Refractive Index: n20/D 1.601(lit.)
• Storage Temp.: Sealed in dry,Room Temperature
• Water Solubility: insoluble
• BRN: 1209545
• CAS DataBase Reference: CINNAMONITRILE(CAS DataBase Reference)
• NIST Chemistry Reference: CINNAMONITRILE(4360-47-8)
• EPA Substance Registry System: CINNAMONITRILE(4360-47-8)

Safety Data

• Hazard Codes: Xi
• Statements: 36/37/38
• Safety Statements: 26-36
• WGK Germany: 3
• RTECS: UD1440000
• F: 9
• TSCA: Yes
• PackingGroup: III
• Hazardous Substances Data: 4360-47-8(Hazardous Substances Data)

Usage

Uses

Used in Perfumery Industry:
Cinnamonitrile is used as a fragrance ingredient for its spicy, slightly floral odor, making it suitable for perfuming soaps and detergents. Its unique scent adds a pleasant aroma to these products, enhancing the overall user experience.
Used in Chemical Synthesis:
Due to its chemical properties, cinnamonitrile can be utilized as a starting material or intermediate in the synthesis of various organic compounds. Its stability to alkali makes it a valuable component in the production of different chemicals and materials.

Trade name

Cinnamalva (IFF)

InChI:InChI=1/C9H7N/c10-8-4-7-9-5-2-1-3-6-9/h1-7H/b7-4-

Upstream product

• 917-64-6 methyl magnesium iodide 
• 60-29-7 diethyl ether 
• 621-79-4 cinnamamide 
• 140-10-3 (E)-3-phenylacrylic acid 
• 592-87-0 lead(II) thiocyanate 
• 20707-70-4 cinnamaldehyde-(Z)-oxime 
• 541-41-3 chloroformic acid ethyl ester 
• 1011-92-3 2-cyano-3-phenylacrylic acid 
• 104-55-2 3-phenyl-propenal 
• 13372-81-1 cinnamaldoxime 
• 14904-40-6 3-phenyl-3-<(trimethylsilyl)oxy>propanenitrile 
• 85936-84-1 benzoyl-4 phenyl-3 butyro nitrile 
• 102-92-1 cinnamoyl chloride 
• 59463-29-5 methoxy-2 phenyl-3 propene nitrile 

Downstream Products

• 95226-68-9 4-cyano-1,2,3-triphenyl-1-butanone 
• 103-26-4 Methyl cinnamate 
• 122-57-6 1-Phenylbut-1-en-3-one 
• 108013-15-6 3,4-Dihydro-5,7-dihydroxy-4-phenylcoumarin 
• 4192-77-2 ethyl cinnamate 
• 4165-96-2 3-phenylglutaric acid 
• 125716-01-0 3-phenyl-2-tripropylstannyl-propionitrile 
• 94-41-7 benzalacetophenone 
• 14371-10-9 (E)-3-phenylpropenal 
• 40019-47-4 cinnamic acid amidoxime 
• 19521-13-2 α,β-dibromo-β-phenylpropionitrile 
• 2038-57-5 3-Phenylpropan-1-amine 
• 14399-84-9 phenylvinylenethioamide 
• 40019-47-4 trans-cinnamamide oxime 

Relevant articles and documents

Highly diastereoselective aziridination of imines with trimethylsilyldiazomethane. Subsequent silyl substitution with electrophiles, ring opening, and metalation of C-silylaziridines - A cornucopia of highly selective transformations

Treatment of a range of N-sulfonyl (Ts and SES) imines derived from aromatic, heteroaromatic, aliphatic, and unsaturated aldehydes with trimethylsilydiazomethane gave C-silylaziridines in good yield (32-83%) and with high diastereoselectivity in favor of the cis product (80:20-100:0). In contrast, an α-imino ester gave predominantly the trans-aziridine (89:11) in high yield (91%). The synthetic potential of C-silylaziridines was investigated. Treatment with F- (tetrabutylammonium triphenyldifluorosilicate was used) in the presence of aldehydes gave the α-hydroxyaziridines in high yield and high diastereoselectivity (86:14-98:2) for the newly created stereogenic center. Complete retention of configuration was observed in the substitution of the silyl group with electrophiles in all cases. Trapping with deuterium (using CDCl3 as electrophile) was also successful, but trapping with phosphate [using CIP(O)(OPh)2] and acetate (using Ac2O) was unsuccessful. In these latter cases ring opening by chloride and acetate, respectively, was observed. Further ring-opening reactions were effected using azide and thiolate nucleophiles and in all cases complete regioselectivity in favor of attack at the silyl-bearing carbon occurred. Complete regioselectivity was also observed in the carbonylative ring expansion using Co2(CO)8 to give a β-lactam. Treatment of cis-1-tosyl-2-phenyl/butyl-3-trimethylsilylaziridines with n-BuLi and subsequent quenching with MeI followed completely different pathways, depending on the 2-substituent. In the case of the 2-phenylaziridine, metalation was initiated α to the phenyl group and led finally to a fused tricyclic adduct with four stereogenic centers as a single diastereoisomer. In the case of the 2-butylaziridine, metalation occurred α to the silyl group and led to a trisubstituted silylaziridine, probably via an azirine intermediate.

Palladium N-methylimidazolium supported complexes as efficient catalysts for the Heck reaction

Different N-methylimidazolium supported ligands have been easily synthesized. The palladium complexes derived from those materials can be used for the catalysis of the Heck reaction giving excellent yields, selectivities and very good TON and TOF values. The supported Pd-pincer complexes show an increased stability, and provide a clear improvement in the recovery and reuse for the supported catalysts.

Pd-smopex-111: A new catalyst for Heck and Suzuki cross-coupling reactions

Smopex-111, a commercially available metal-scavenging styryl thiol-grafted polyolefin fiber was treated with palladium acetate giving a reagent with a palladium loading of 4.4-4.7 (wt %). The Pd-Smopex-111 thus generated was found to be a highly active catalyst for Heck and Suzuki coupling reactions and was found to be reusable with negligible leaching of palladium.

Pd(0) supported onto monolithic polymers containing IL-like moieties. Continuous flow catalysis for the Heck reaction in near-critical EtOH

Long-term stable Pd(0) catalysts can be easily supported onto polymeric monoliths containing methyl-imidazole moieties and the corresponding reactors based on these materials can be applied for the continuous Heck reaction in near-critical EtOH. The Royal Society of Chemistry 2006.

Palladium-catalyzed synthesis of nitriles from N-phthaloyl hydrazones

The Pd-catalyzed transformation of N-phthaloyl hydrazones into nitriles involving the cleavage of an N-N bond is reported. The use of N-heterocyclic carbene as a ligand is essential for the success of the reaction. N-Phthaloyl hydrazones prepared from aromatic aldehydes or cyclobutanones are applicable to this transformation, which gives aryl or alkenyl nitriles, respectively.

Decarbonylative Synthesis of Aryl Nitriles from Aromatic Esters and Organocyanides by a Nickel Catalyst

A decarbonylative cyanation of aromatic esters with aminoacetonitriles in the presence of a nickel catalyst was developed. The key to this reaction was the use of a thiophene-based diphosphine ligand, dcypt, permitting the synthesis of aryl nitrile without the generation of stoichiometric metal- or halogen-containing chemical wastes. A wide range of aromatic esters, including hetarenes and pharmaceutical molecules, can be converted into aryl nitriles.

NiFe2O4@SiO2@ZrO2/SO42-/Cu/Co nanoparticles: A novel, efficient, magnetically recyclable and bimetallic catalyst for Pd-free Suzuki, Heck and C-N cross-coupling reactions in aqueous media

The novel heterogeneous bimetallic nanoparticles of Cu-Co were synthesized based on magnetic nanoparticles, and the magnetic nanocatalyst was characterized by XRD, FE-SEM, EDX mapping, BET, TEM, HRTEM, FTIR, TGA, and VSM. This catalyst was successfully applied as a recyclable magnetically catalyst in Heck, Suzuki, and C-N cross-coupling reactions with various aryl halides (iodides, bromides, and chlorides as challengeable substrates), with olefins, phenylboronic acid, and amines, respectively. We considered the rise of synergetic effects from the different Lewis acid and Br?nsted acid sites present in the catalyst. The catalyst was synthesized with cheap, available materials and a simple synthesis method. The catalyst can be separated easily using an external magnet. It was recycled for more than ten runs without a sensible loss of its catalytic activity, and no significant leaching of the Cu and Co quantity was observed. The significant benefits of the method are high-level generality, simple operation, and there are no heavy metals and toxic solvents. This is a quick, easy, efficacious and environmentally friendly protocol, and no by-products are formed in the reaction. These features make it an appropriate practical alternative protocol. In comparison with recent works, the other advantage of this catalyst is the synthesis of a wide variety of C-C and C-N bond derivatives (more than 40 derivatives). The other significant advantage is the low temperature of the reaction and the use of the least possible amount of the catalyst (0.003 g). The efficiency was good to excellent and the catalyst selectivity has been high. We aspire that our study inspires more interest to design novel catalysts based on using low-cost metal ions (such as cobalt and copper) in the cross-coupling reactions. This journal is

Cu2O-Catalyzed Conversion of Benzyl Alcohols Into Aromatic Nitriles via the Complete Cleavage of the C≡N Triple Bond in the Cyanide Anion

Nitrogen transfer from cyanide anion to an aldehyde is emerging as a promising method for the synthesis of aromatic nitriles. However, this method still suffers from a disadvantage that a use of stoichiometric Cu(II) or Cu(I) salts is required to enable the reaction. As we report herein, we overcame this drawback and developed a catalytic method for nitrogen transfer from cyanide anion to an alcohol via the complete cleavage of the C≡N triple bond using phen/Cu2O as the catalyst. The present condition allowed a series of benzyl alcohols to be smoothly converted into aromatic nitriles in moderate to high yields. In addition, the present method could be extended to the conversion of cinnamic alcohol to 3-phenylacrylonitrile.

A new palladium heterogeneous complex (Pd-Gu@BOEH): chemoselective, phosphine-free and practical nanocatalyst in carbon–carbon cross-coupling reaction

Herein, boehmite nanoparticles were synthesized via combination of Al(NO3)3·9H2O and NaOH in aqueous solution. This nanomaterial converted to Pd-Gu@BOEH in several sequences. Pd-Gu@BOEH was used as efficient and recoverable nanocatalyst for the chemoselective C–C band formation such as Mizoroki–Heck and Suzuki–Miyaura reactions without any phosphine ligands or inert atmosphere. This catalyst has been characterized by several analyses such as EDS, WDX, SEM, XRD, FT-IR, TEM, TGA, AAS and BET. Also, obtained products from C–C coupling reactions were identified by NMR spectroscopy and their melting points. This catalyst was recycled in described reactions without palladium leaching. The reused catalyst was characterized by EDS, WDX, XRD, FT-IR and AAS analysis, which showed good stability during reaction process.

The Mizoroki-Heck reaction in mesoionic 1-butyl-3-methyltetrazolium-5-olate

1-Butyl-3-methyltetrazolium-5-olate (1), a mesoionic compound, exists as a liquid at room temperature and can be used as a polar solvent for the Mizoroki-Heck reaction, wherein it has been proven to be a superior solvent to other solvents. The reaction of iodobenzene with ethyl acrylate in the presence of palladium acetate in mesoionic liquid 1 at 40 °C for 24 h gave ethyl cinnamate in 78% yield in the absence of ligands, while the use of other solvents, such as [bmim][BF4], [bmim][PF6], and DMF gave lower yields (43%, 37%, and 17%, respectively) under the same conditions. Heck-type coupling reactions of electron-deficient or electron-rich aryl iodides and bromobenzenes with olefins (15 examples, 7%–97%) were performed in 1. When a phosphine ligand was added to the reaction mixture, aryl bromides could be used, and the mesoionic liquid containing the catalysts could be reused at least five times.