852913-22-5Relevant academic research and scientific papers
Thiocarbonyl Surrogate via Combination of Sulfur and Chloroform for Thiocarbamide and Oxazolidinethione Construction
Tan, Wei,Wei, Jianpeng,Jiang, Xuefeng
supporting information, p. 2166 - 2169 (2017/04/27)
An efficient and practical thiocarbonyl surrogate via combination of sulfur and chloroform has been developed. A variety of thiocarbamides and oxazolidinethiones have been established, including chiral thiourea catalysts and chiral oxazolidinethione auxiliaries with high selectivity. Meanwhile, pesticides Diafenthiuron (an acaricide), ANTU (a rodenticide), and Chloromethiuron (an insecticide) were practically synthesized through this method in gram scale. Dicholorocarbene, as the key intermediate, was further confirmed via a carbene-trapping control experiment.
Solvent-free enantioselective conjugate addition and bioactivities of nitromethane to Chalcone containing pyridine
Zhang, Guoping,Zhu, Chun,Liu, Dengyue,Pan, Jianke,Zhang, Jian,Hu, Deyu,Song, Baoan
, p. 129 - 136 (2016/12/23)
A series of chiral thioureas derived from quinine were tested as catalysts in the enantioselective Michael additions of nitromethane to α,β-unsaturated ketones containing pyridine. The best results were obtained with the bifunctional catalyst prepared from 3,5-di(trifluoromethyl)-aniline under solvent-free conditions. This thiourea promoted the reaction with high enantioselectivities and chemical yields for aryl ketones. The origins of enantioselectivity were further investigated via experiment and computation. Meanwhile, the products from our reaction showed potent antibacterial activities against rice bacterial leaf blight, with the S-enantiomer performing much better than the R-enantiomer. Given the promising bioactivity of this class of molecules, our work is expected to offer important applications in developing future generations for drug design.
Combined bead polymerization and Cinchona organocatalyst immobilization by thiol-ene addition
Fredriksen, Kim A.,Kristensen, Tor E.,Hansen, Tore
body text, p. 1126 - 1133 (2012/09/05)
In this work, we report an unusually concise immobilization of Cinchona organocatalysts using thiol-ene chemistry, in which catalyst immobilization and bead polymerization is combined in a single step. A solution of azo initiator, polyfunctional thiol, polyfunctional alkene and an unmodified Cinchona-derived organocatalyst in a solvent is suspended in water and copolymerized on heating by thiol-ene additions. The resultant spherical and gel-type polymer beads have been evaluated as organocatalysts in catalytic asymmetric transformations.
