39755-15-2

Usage

Synthesis Reference(s)

Synthetic Communications, 25, p. 101, 1995 DOI: 10.1080/00397919508010794

InChI:InChI=1/C14H17NO/c15-12-8-3-1-2-7-11-14(16)13-9-5-4-6-10-13/h4-6,9-10H,1-3,7-8,11H2

Upstream product

• 629-40-3 octanedinitrile 
• 98-80-6 phenylboronic acid 
• 2082-21-5 1-phenylcycloheptanol 
• 7677-24-9 trimethylsilyl cyanide 
• 37908-41-1 1-hydroperoxy-1-phenylcycloheptane 
• 98-83-9 isopropenylbenzene 
• 98-86-2 acetophenone 
• 25328-90-9 1-phenylcyclooct-1-ene 
• 137407-47-7 (E)-1-phenylcyclooctene 
• 20965-27-9 7-bromo-heptanonitrile 
• 98-88-4 benzoyl chloride 

Relevant academic research and scientific papers

In-situ-generation of alkylsilyl peroxides from alkyl hydroperoxides and their subsequent copper-catalyzed functionalization with organosilicon compounds

Alkylsilyl peroxides were generated in situ from the corresponding alkyl hydroperoxides using organosilicon compounds of the type Me3SiX (X = CN, N3, and halogens) and an amine base. Subsequent in situ copper-catalyzed homolytic cleavage of the alkylsilyl peroxides afforded alkyl radicals, which were then trapped with X (X = CN, N3, and halogens) to furnish products with new carbon-carbon, carbon-nitrogen, or carbon-halogen bonds in good to high yields.

The Formation of C-C or C-N Bonds via the Copper-Catalyzed Coupling of Alkylsilyl Peroxides and Organosilicon Compounds: A Route to Perfluoroalkylation

The copper-catalyzed selective cleavage of alkylsilyl peroxides and the subsequent formation of carbon-carbon or carbon-nitrogen bonds with organosilicon compounds are described. The reaction proceeds under mild conditions and exhibits a broad substrate scope with respect to both cyclic and acyclic alkylsilyl peroxides in combination with carbon and nitrogen sources. In particular, this approach enables the facile radical perfluoroalkylation using commercially available perfluoroalkyltrimethylsilanes. Our mechanistic studies suggest that the reaction should proceed via a free-radical process.

Syntheses of Pyrroles, Pyridines, and Ketonitriles via Catalytic Carbopalladation of Dinitriles

The first example of the Pd-catalyzed addition of organoboron reagents to dinitriles, as an efficient means of preparing 2,5-diarylpyrroles and 2,6-diarylpyridines, has been discussed here. Furthermore, the highly selective carbopalladation of dinitriles with organoboron reagents to give long-chain ketonitriles has been developed as well. Based on the broad scope of substrates, excellent functional group tolerance, and use of commercially available substrates, the Pd-catalyzed addition reaction of arylboronic acid and dinitriles is expected to be significant in future synthetic procedures.

TEMPO-catalyzed aerobic oxygenation and nitrogenation of olefins via C=C double-bond cleavage

A novel TEMPO-catalyzed aerobic oxygenation and nitrogenation of hydrocarbons via C=C double-bond cleavage has been disclosed. The reaction employs molecular oxygen as the terminal oxidant and oxygen-atom source by metal-free catalysis under mild conditions. This method can be used for the preparation of industrially and pharmaceutically important N- and O-containing motifs, directly from simple and readily available hydrocarbons.

Facile Synthesis of Keto Nitriles by Cu(II)-Promoted Photooxidative Cleavage of Cyclic Olefins

Reaction of trisubstituted cyclic olefins with NaN3 in the presence of Cu(OTf)2 upon irradiation under oxygen gave keto nitriles in good yields. 1,5-Dimethyl-1,5-cyclooctadiene and 1,5,9-trimethyl-1,5,9-cyclododecatriene were converted into the corresponding unsaturated keto nitriles.

The Direct Formation of Functionalized Alkyl(aryl)zinc Halides by Oxidative Addition of Highly Reactive Zinc with Organic Halides and Their Reactions with Acid Chlorides, α,β-Unsaturated Ketones, and Allylic, Aryl, and Vinyl Halides

Highly reactive zinc, prepared by the lithium naphthalenide reduction of ZnCl2, readily undergoes oxidative addition to alkyl, aryl, and vinyl halides under mild conditions to generate the corresponding organozinc compounds in excellent yields.Significantly, the reaction will tolerate a spectrum of functional groups on the organic halides.Accordingly, this approach can now be used to prepare a wide variety of highly functionalized organozinc compounds.In the presence of Cu(I) salts, the organozinc compounds cross-couple with acid chlorides, conjugatively add to α,β-unsaturated ketones, and regioselectively undergo SN2' substitution reactions with allylic halides.They also cross-couple with aryl or vinyl halides with Pd(0) catalysts.