71899-75-7Relevant articles and documents
Copper-Catalyzed Aerobic Oxidative Cleavage of Unstrained Carbon-Carbon Bonds of 1,1-Disubstituted Alkenes with Sulfonyl Hydrazides
Yi, Dong,He, Linying,Qi, Zhongyu,Zhang, Zhijie,Li, Mengshun,Lu, Ji,Wei, Jun,Du, Xi,Fu, Qiang,Wei, Siping
, p. 859 - 865 (2021/03/04)
Alkoxy radical-mediated carbon-carbon bond cleavages have emerged as a powerful strategy to complement traditional ionic-type transformations. However, carbon-carbon cleavage reaction triggered by alkoxy radical intermediate derived from the combination of alkyl radical and dioxygen, is scarce and underdeveloped. Herein, we report alkoxy radical, which was generated from alkyl radical and dioxygen, mediated selective cleavage of unstrained carbon-carbon bond for the oxysulfonylation of 1,1-disubstituted alkenes, providing facile access to a variety of valuable β-keto sulfones. Mechanistic experiments indicated alkoxy radical intermediate that underwent subsequent regioselective β-scission might be involved in the reaction and preliminary computational studies were conducted to provide a detailed explanation on the regioselectivity of the C—C bond cleavage. Notably, the strategy was successfully applied for constructing uneasily obtained architecturally intriguing molecules.
A Compartmentalized-type Bifunctional Magnetic Catalyst for One-pot Aerobic Oxysulfonylation and Asymmetric Transfer Hydrogenation
Wang, Shitong,Wang, Chengyi,Lv, Ning,Tan, Chunxia,Cheng, Tanyu,Liu, Guohua
, p. 909 - 915 (2020/11/30)
Utilization of the confined cavity of the mesoporous silica, the exploration of the synergetic catalysis process for sequential organic transformations has great significance in asymmetric catalysis. In this study, the yolk-shell-structured magnetic nanoparticles with the chiral Ru/diamine species within the nanochannels of the outer mesoporous silica shell and the FeCl3 species on the inner magnet core are fabricated. The electron microscopy images and the structural characterizations disclose the uniformly distributed magnetic nanoparticles with the well-defined single-site ruthenium/diamine active centers onto the outer silica shell. As a yolk-shell-structured bifunctional magnet catalyst, the FeCl3 species enables an efficient aerobic oxysulfonylation between aryl-substituted terminal alkynes and sodium sulfinates to the β-keto sulfones intermediates, and the ruthenium/diamine species sequentially reduces the in-situ generated intermediate to the chiral β-hydroxysulfones products. As we envision, this one-pot aerobic oxysulfonylation/asymmetric transfer hydrogenation process affords various chiral β-hydroxysulfones in high yields with excellent enantioselectivities. Furthermore, this magnetic catalyst can also be conveniently recovered via an additional outer magnet and repeatedly recycled, showing a potential application in industrial interest.
Copper-Catalyzed Chloro-Arylsulfonylation of Styrene Derivatives via the Insertion of Sulfur Dioxide
Li, Yue,Shen, Lin,Zhou, Mi,Xiong, Baojian,Zhang, Xuemei,Lian, Zhong
supporting information, p. 5880 - 5884 (2021/08/01)
A copper-catalyzed four-component chloro-arylsulfonylation of styrene derivatives with aryldiazonium tetrafluoroborates, lithium chloride, and ex-situ generated sulfur dioxide (from SOgen) is presented. This sulfonylation features good functional group compatibility, mild reaction conditions, excellent regioselectivity, and good yields. The robustness and potential of this method have also been successfully demonstrated by a gram-scale reaction. Based on experimental study, a radical-involved mechanism is proposed for the transformation.