Kevin Wu1, Abigail G Doyle1. 1. Department of Chemistry, Princeton University, Princeton, New Jersey 08544, USA.
Abstract
The field of Ni-catalysed cross-coupling has seen rapid recent growth because of the low cost of Ni, its earth abundance, and its ability to promote unique cross-coupling reactions. Whereas advances in the related field of Pd-catalysed cross-coupling have been driven by ligand design, the development of ligands specifically for Ni has received minimal attention. Here, we disclose a class of phosphines that enable the Ni-catalysed Csp3 Suzuki coupling of acetals with boronic acids to generate benzylic ethers, a reaction that failed with known ligands for Ni and designer phosphines for Pd. Using parameters to quantify phosphine steric and electronic properties together with regression statistical analysis, we identify a model for ligand success. The study suggests that effective phosphines feature remote steric hindrance, a concept that could guide future ligand design tailored to Ni. Our analysis also reveals that two classic descriptors for ligand steric environment-cone angle and % buried volume-are not equivalent, despite their treatment in the literature.
The field of Ni-n class="Chemical">catalysed n class="Chemical">cross-coupling has seen rapid recent growth because of the low cost of Ni, its earth abundance, and its ability to promote unique cross-coupling reactions. Whereas advances in the related field of Pd-catalysed cross-coupling have been driven by ligand design, the development of ligands specifically for Ni has received minimal attention. Here, we disclose a class of phosphines that enable the Ni-catalysed Csp3 Suzuki coupling of acetals with boronic acids to generate benzylicethers, a reaction that failed with known ligands for Ni and designer phosphines for Pd. Using parameters to quantify phosphine steric and electronic properties together with regression statistical analysis, we identify a model for ligand success. The study suggests that effective phosphines feature remote steric hindrance, a concept that could guide future ligand design tailored to Ni. Our analysis also reveals that two classic descriptors for ligand steric environment-cone angle and % buried volume-are not equivalent, despite their treatment in the literature.
Authors: Carin C C Johansson Seechurn; Matthew O Kitching; Thomas J Colacot; Victor Snieckus Journal: Angew Chem Int Ed Engl Date: 2012-05-09 Impact factor: 15.336
Authors: Cheng Fang; Marco Fantin; Xiangcheng Pan; Kurt de Fiebre; Michelle L Coote; Krzysztof Matyjaszewski; Peng Liu Journal: J Am Chem Soc Date: 2019-04-29 Impact factor: 15.419
Authors: Gang Lu; Richard Y Liu; Yang Yang; Cheng Fang; Daniel S Lambrecht; Stephen L Buchwald; Peng Liu Journal: J Am Chem Soc Date: 2017-11-09 Impact factor: 15.419
Authors: L Reginald Mills; David Gygi; Jacob R Ludwig; Eric M Simmons; Steven R Wisniewski; Junho Kim; Paul J Chirik Journal: ACS Catal Date: 2022-01-20 Impact factor: 13.700
Authors: Amanda J Bischoff; Brandon M Nelson; Zachary L Niemeyer; Matthew S Sigman; Mohammad Movassaghi Journal: J Am Chem Soc Date: 2017-10-18 Impact factor: 15.419
Authors: Xin Yi See; Xuelan Wen; T Alexander Wheeler; Channing K Klein; Jason D Goodpaster; Benjamin R Reiner; Ian A Tonks Journal: ACS Catal Date: 2020-11-05 Impact factor: 13.084