Nickel‐Catalyzed Transfer Hydrogenation of Unactivated Aryl Alkenes with Hydrosilane as Hydrogen Source

Abstract: A nickel‐catalyzed transfer hydrogenation of aryl alkenes has been developed using hydrosilane as the hydrogen source. Sterically hindered disubstituted or trisubstituted alkenes were employed to test the efficiency of this transformation. Mechanism studies showed that hydrogenation took place smoothly with more sterically‐hindered trans‐alkenes. While uncongested cis‐alkenes could hardly convert to the alkanes but hydrosilylation products were generated instead. Moreover, certain amount of water was found to … Show more

“…The chemically stored hydrogen can be released by the use of a catalyst to kinetically favor H 2 evolution under mild experimental conditions up to 3 mol of H 2 per mole of AB (eq ) normalH 3 N − B normalH 3 + 2 normalH 2 O → 3 H 2 ↑ + normalN H 4 normalB O 2 AB is also the reducing agent for a wide range of applications, spanning from the reductive transformation of unsaturated organic compounds to biomass refinement and fuel production up to the synthesis of pharmacologically active compounds and commodities . Most of these reduction processes make use of pressurized molecular hydrogen gas for the direct substrate hydrogenation (DH) or liquid hydrogen sources such as alcohols, formic acid, and hydrosilanes for transfer hydrogenation (TH) processes. Conventionally, reactions carried out with molecular dihydrogen gas (DH) require specialized equipment for pressurized and flammable gas manipulation that poses a number of safety concerns.…”

Ultrasmall Nickel Nanoparticles on a Covalent Triazine Framework for Ammonia Borane Hydrolysis and Transfer Hydrogenation of Nitroaromatics

“…The chemically stored hydrogen can be released by the use of a catalyst to kinetically favor H 2 evolution under mild experimental conditions up to 3 mol of H 2 per mole of AB (eq ) normalH 3 N − B normalH 3 + 2 normalH 2 O → 3 H 2 ↑ + normalN H 4 normalB O 2 AB is also the reducing agent for a wide range of applications, spanning from the reductive transformation of unsaturated organic compounds to biomass refinement and fuel production up to the synthesis of pharmacologically active compounds and commodities . Most of these reduction processes make use of pressurized molecular hydrogen gas for the direct substrate hydrogenation (DH) or liquid hydrogen sources such as alcohols, formic acid, and hydrosilanes for transfer hydrogenation (TH) processes. Conventionally, reactions carried out with molecular dihydrogen gas (DH) require specialized equipment for pressurized and flammable gas manipulation that poses a number of safety concerns.…”

Ultrasmall Nickel Nanoparticles on a Covalent Triazine Framework for Ammonia Borane Hydrolysis and Transfer Hydrogenation of Nitroaromatics

Economic analysis of hydrogen refueling station considering different operation modes

Mechanistic investigation and machine learning exploration of structure-activity relationship of NHC-Mn catalyzed ester hydrosilylation reaction