5558-34-9

Upstream product

• 140-29-4 phenylacetonitrile 
• 769-68-6 2-phenylbutanenitrile 
• 107-82-4 i-pentyl bromide 
• 123-51-3 i-Amyl alcohol 

Downstream Products

• 58422-74-5 α-Peracetoxy-α-phenylisoheptannitril 
• 102746-82-7 2-(3-Methyl-butyl)-2-phenyl-pentanedinitrile 
• 5558-48-5 5-methyl-2-phenylhexanoic acid 
• 58422-87-0 2,2-dimethyl-5-oxo-5-phenylpentanenitrile 
• 102746-52-1 3-(4-Amino-phenyl)-3-(3-methyl-butyl)-piperidine-2,6-dione 
• 102746-60-1 3-isopentyl-3-phenyl-piperidine-2,6-dione 

Relevant academic research and scientific papers

Iron-Catalyzed Alkylation of Nitriles with Alcohols

A general, efficient iron-catalyzed α-alkylation of nitriles with primary alcohols through a hydrogen-borrowing pathway has been developed, allowing a wide variety of alkylated nitriles to be readily accessible. Detailed mechanistic studies suggest that the reaction proceeds via an olefin intermediate with the turnover rate limited by the hydrogenation of the olefin with an iron hydride. Apart from participating in the alkylation, the nitrile is found to play an important role in promoting the formation of and stabilizing the active catalytic species.

Facile Ruthenium(II)-Catalyzed α-Alkylation of Arylmethyl Nitriles Using Alcohols Enabled by Metal-Ligand Cooperation

A facile ruthenium(II)-catalyzed α-alkylation of arylmethyl nitriles using alcohols is reported. The ruthenium pincer catalyst serves as an efficient catalyst for this atom-economical transformation that undergoes alkylation via borrowing hydrogen pathways, producing water as the only byproduct. Arylmethyl nitriles containing different substituents can be effectively alkylated using diverse primary alcohols. Notably, using ethanol and methanol as alkylating reagents, challenging ethylation and methylation of arylmethyl nitriles were performed. Secondary alcohols do not undergo alkylation reactions. Thus, phenylacetonitrile was chemoselectively alkylated using primary alcohols in the presence of secondary alcohols. Diols provided a mixture of products. When deuterium-labeled alcohol was used, the expected deuterium transposition occurred, providing both α-alkylation and α-deuteration of arylmethyl nitriles. Consumption of nitrile was monitored by GC, which indicated the involvement of first-order kinetics. Plausible mechanistic pathways are suggested on the basis of experimental evidence. The ruthenium catalyst reacts with base and generates an unsaturated intermediate, which further reacts with both nitriles and alcohols. While nitrile is transformed to enamine via [2 + 2] cycloaddition, alcohol is oxidized to aldehyde. The metal bound enamine adduct reacts with aldehyde via Michael addition, resulting in an ene-imine adduct, which perhaps undergoes direct hydrogenation by a Ru dihydride intermediate, produced from alcohol oxidation. However, in situ monitoring of the reaction mixture confirmed the presence of unsaturated vinyl nitrile in the reaction mixture in minor amounts (10%), indicating the possible dissociation of ene-imine adduct during the catalysis, which may further be hydrogenated to provide the α-alkylated nitriles. Overall, the efficient α-alkylation of nitriles using alcohols can be attributed to the amine-amide metal-ligand cooperation that is operative in the ruthenium pincer catalyst, which enables all of the catalytic intermediates to remain in the +2 oxidation state throughout the catalytic cycle.

Oxidative Decyanation of Secondary Nitriles to Ketones

Procedures for the oxidative decyanation of secondary nitriles to ketones involve (1) iodination of N-(trialkylsilyl)ketenimines derived from secondary nitriles and subsequent hydrolysis of the α-iodo nitriles with silver oxide, (2) addition of nitrosobenzene to N-(trialkylsilyl)ketenimines, (3) conversion of secondary nitriles to α-(phenylthio) nitriles and subsequent hydrolysis with N-bromosuccinimide in aqueous acetonitrile, and (4) preparation of α-hydroperoxy nitriles by direct oxygenation of anions of secondary nitriles and subsequent reductive hydrolysis with stannous chloride followed by sodium hydroxide.The latter general procedure was applied to various secondary nitriles bearing dialkyl, aryl and alkyl, and diaryl substituents to provide ketones in good yield and was extended to the oxidative decyanation of α,β-unsaturated nitriles to furnish α,β-unsaturated ketones.