Nickel-Catalyzed α-Benzylation of Arylacetonitriles via CO Activation

The exploration of deoxygenation reactions for alcohols and derivatives using earth-abundant reagents

In Earth matter evolution, the deoxygenation process plays a central role as plant and animal remains, which are composed by highly oxygenated molecules, were gradually deoxygenated into hydrocarbons to give fossil fuels deep in the Earth crust. The understanding of this process is becoming crucial to the entire world and to the sustainable development of mankind. This review provides a brief summary of the extensive deoxygenation research under mild, potentially sustainable conditions. We also summarize some challenges and opportunities for potential deoxygenation reactions in the future.

Iodine Promoted Conversion of Esters to Nitriles and Ketones under Metal-Free Conditions

We report a novel strategy to prepare valuable nitriles and ketones through the conversion of esters under metal-free conditions. By using the I₂/PCl₃ system, various substrates including aliphatic and aromatic esters could react with acetonitrile and arenes to afford the desired products in good to excellent yields. This method is compatible with a number of functional groups and provides a simple and practical approach for the synthesis of nitrile compounds and aryl ketones.

Ruthenium-catalyzed benzylic substitution of benzyl esters with stabilized carbon nucleophiles

We have accomplished the ruthenium-catalyzed benzylic substitution of benzyl esters with a stabilized carbon nucleophile. A [Cp*RuCl2]2/picolinic acid catalyst system promoted the reaction of 2-naphthylmethyl-2,3,4,5,6-pentafluorobenzoates with a series of stabilized carbon nucleophiles such as malonates, β-ketoesters, and diketones to give the corresponding benzylic alkylation products in moderate to high yields. We proposed a plausible reaction mechanism that could involve a (π-benzyl)ruthenium intermediate.

Phosphonic acid mediated practical dehalogenation and benzylation with benzyl halides

For the first time, by using H₃PO₃/I₂ system, various benzyl chlorides, bromides and iodides were dehalogenated successfully. In the presence of H₃PO₃, benzyl halides underwent electrophilic substitution reactions with electron-rich arenes, leading to a broad range of diarylmethanes in good yields. These transformations feature green, cheap reducing reagents and metal-free conditions. A possible mechanism was proposed.

A practical method for phosphonic acid mediated dehalogenation and benzylation with benzyl halides was developed.