15463-92-0Relevant articles and documents
Room-temperature Pd-catalyzed methoxycarbonylation of terminal alkynes with high branched selectivity enabled by bisphosphine-picolinamide ligand
Chen, Fen-Er,Ke, Miaolin,Liu, Ding,Ning, Yingtang,Ru, Tong
supporting information, p. 1041 - 1044 (2022/01/28)
We report the room-temperature Pd-catalyzed methoxy-carbonylation with high branched selectivity using a new class of bisphosphine-picolinamide ligands. Systematic optimization of ligand structures and reaction conditions revealed the significance of both
Investigation of the Mechanism Behind Conductive Fluorescent and Multistimuli-responsive Li+-enriched Metallogel Formation
Dixit, Manish K.,Dubey, Mrigendra,Kalam, Abul,Kumar, Yeeshu,Mahendar, Chinthakuntla,Sharma, Vinay K.,Shukla, Jay
, p. 3020 - 3028 (2020/09/04)
A fluorescent metallogel (2.6 % w/v) has been obtained from two non-fluorescent components viz. phenyl-succinic acid derived pro-ligand H2PSL and LiOH (2 equiv.) in DMF. Li+ ion not only plays a crucial role in gelation through aggre
Synergetic Catalysis for One-pot Bis-alkoxycarbonylation of Terminal Alkynes over Pd/Xantphos?Al(OTf)3 Bi-functional Catalytic System
Guo, Wen-Di,Liu, Lei,Yang, Shu-Qing,Chen, Xiao-Chao,Lu, Yong,VO-Thanh, Giang,Liu, Ye
, p. 1376 - 1384 (2020/01/24)
Tandem bis-alkoxycarbonylation of alkynes allows for the preparation of 2-substituted succinates from alkynes and nucleophile alcohol via two successive alkoxycarbonylation with advantages of 100 % atomic economy and simplified one-pot operation. Herein, the one-pot tandem bis-alkoxycarbonylation of alkynes was accomplished over the bi-functional catalytic system containing Xantphos-modified Pd-complex and Lewis super-acid of Al(OTf)3. It was found that, via the synergetic catalysis, the involved Xantphos-modified Pd-complex was responsible for the activation of CO and the alkynes through coordination to Pd-center while Al(OTf)3 was in charge of the activation of the alcohol to facilitate the formation of [Pd?H]+ active species. The in situ high-pressure FT-IR analysis, coupled with 1H/13C NMR spectral characterizations, confirmed that the introduced Al(OTf)3 with intensive oxophilicity (via acid-base pair interaction) was able to activate nucleophilic MeOH to be a reliable proton-donor (i. e. hydride-source) to warrant the formation and stability of [Pd?H]+ species upon the oxidation of Pd0 by H+ (Pd0+H+→[PdII?H]+). Over the developed bi-functional catalytic system, the yields of the target diesters were obtained in the range of 36~86 % in this sequence with the wide substrate scope.