19135-08-1Relevant articles and documents
Mercury-free preparation and selective reactions of propargyl (and propargylic) grignard reagents
Acharya, Hukum P.,Miyoshi, Kei,Kobayashi, Yuichi
, p. 3535 - 3538 (2007)
ZnBr2 was found to catalyze formation of propargyl and propargylic Grignard reagents, and thus put an end to the standard method using a mercury catalyst. The Grignard reagents were submitted to addition reaction with carbonyl compounds and allylation with the cyclic monoacetate to afford the propargyl-type products selectively. Furthermore, the product from the monoacetate was transformed to an acetylene analogue of 2-(5,6-epoxyisoprostane A2)phosphorylcholines.
One-pot, regioselective synthesis of homopropargyl alcohols using pro-pargyl bromide and carbonyl compound by the mg-mediated reaction under solvent-free conditions
Devaramani, Samrat,Li, Shunxi,Ma, Xiaofang,Xu, Daqian,Zhao, Guohu
supporting information, p. 438 - 442 (2020/04/21)
The elimination of volatile organic solvents in organic synthesis is the most important goal in “Green” chemistry. We report a simple, efficient and facile method for the addition of progargyl bromide to carbonyl compounds using Mg metal as a mediator under solvent-free conditions which could regioselectively generate homopropargyl alcohols efficiently in good to excellent yields. The procedure has advantages such as short reaction time, operationally simple, excellent product yields, high regioselectivity and organic solvent-free.
Zinc Amide Catalyzed Regioselective Allenylation and Propargylation of Ketones with Allenyl Boronate
Yamashita, Yasuhiro,Cui, Yi,Xie, Peizhong,Kobayashi, Shu
supporting information, p. 6042 - 6045 (2016/01/09)
Zinc amide catalyzed, regioselective allenylation and propargylation of ketones with allenyl boronate is reported. Tertiary allenyl and homopropargyl alcohols were obtained, respectively, in high selectivities, from the same starting materials, simply by changing the reaction conditions. The substrate scope was wide. Mechanistic studies suggest that the reactions are controlled under kinetic and thermodynamic conditions.