56427-44-2Relevant articles and documents
Understanding the Use of Phosphine-(EWO) Ligands in Negishi Cross-Coupling: Experimental and Density Functional Theory Mechanistic Study
Gioria, Estefanía,del Pozo, Juan,Lledós, Agustí,Espinet, Pablo
supporting information, p. 2272 - 2282 (2021/05/05)
The easily prepared hemilabile ligand 1-(PPh2),2-(trans-CH═CHCOPh)-C6F4(PhPEWO-F) and other PEWO ligands are well-known promoters of C-C reductive eliminations and very effective in Negishi couplings. As an example, the efficient Negishi coupling of (C6F5)-I and Zn(C6F5)2is reported. The thorough experimental study of the steps involved in the catalytic cycle uncovers the potential weakness of this ligand that could frustrate at some points the desired cycle and provide some simple precautions to keep the catalytic cycle working efficiently. Density functional theory (DFT) calculations complete the experimental study and provide insight into nonobservable transition states and intermediates, comparing the potential conflict between reductive elimination and olefin insertion. Our results showcase the importance the transmetalation step, facilitated by the strong trans effect of the electron-withdrawing ligand, and the choice of organozinc nucleophiles, critical to ensure fast group exchange and a positive outcome of the catalytic reactions.
Experimental study of the mechanism of the palladium-catalyzed aryl-alkyl negishi coupling using hybrid phosphine-electron-withdrawing olefin ligands
Gioria, Estefana,Martnez-Ilarduya, Jess M.,Espinet, Pablo
, p. 4394 - 4400 (2015/04/16)
A detailed study of the Negishi cross-coupling reaction of ArI (Ar = 2-C6H4CO2Et) and ZnEt2 with palladium catalysts containing conventional phosphines versus one using a chelating hybrid phosphine-electron-withdrawing olefin (P-EWO) ligand reveals that for conventional phosphines (e.g., PPh3) β-H elimination from intermediate [PdArEt(PPh3)2] is competitive with Ar-Et reductive elimination and is responsible for part of the undesired reduction product ArH. In contrast, with the EWO phosphine, the β-H elimination from intermediate [PdArEt(P-EWO)] is slow compared to the fast Ar-Et reductive elimination, and the undesired reduction product ArH observed proceeds in this case of hydrolysis of ZnArEt, formed in transmetalations where Ar is transferred from Pd to Zn. The rate of these transmetalations is comparable to the rate of reductive eliminations. Consequently, undesired transmetalations affording [PdEt2(P-EWO)] and ZnArEt are more effective at early stages of the reactions and less effective when the ethylating agent becomes poorer in ZnEt2 and richer in ZnEtX (X = I), as the reaction proceeds. Careful analysis of the experiments reveals the detailed changing evolution of the reaction, not only providing the main features of the catalytic cycle but also deducing how the reagents in the system change with time and what the effects on the products of these changes are.
Superior effect of a π-acceptor ligand (phosphine-electron-deficient olefin ligand) in the Negishi coupling involving alkylzinc reagents
Luo, Xiancai,Zhang, Heng,Duan, Hui,Liu, Qiang,Zhu, Lizheng,Zhang, Tony,Lei, Aiwen
, p. 4571 - 4574 (2008/03/12)
(Chemical Equation Presented) Palladium-catalyzed Negishi cross-coupling involving primary and secondary alkyls, even in the presence of β-H, can be achieved at ambient temperature using chelating ligands containing a phosphine and an electron-deficient olefin. The superior effects of the ligands were shown not only in the desired cross-coupling product yields but also in the fast reaction at mild conditions. This reaction has been also scaled up to 50 g in 0.005 mol % catalyst (20,000 TONs) at room temperature.