14311-75-2Relevant articles and documents
Iron-Catalyzed Silylation of (Hetero)aryl Chlorides with Et3SiBpin
Jia, Jia,Zeng, Xiaoqin,Liu, Zhengli,Zhao, Liang,He, Chun-Yang,Li, Xiao-Fei,Feng, Zhang
, p. 2816 - 2821 (2020)
To date, the iron-catalyzed construction of C-heteroatom bonds has been less developed due to the difficulty of transmetalation with heteroatom anions and the sluggish reductive elimination. Herein we report an iron-catalyzed method for the silylation of
Silylation of Aryl Chlorides by Bimetallic Catalysis of Palladium and Gold on Alloy Nanoparticles
Miura, Hiroki,Masaki, Yosuke,Fukuta, Yohei,Shishido, Tetsuya
supporting information, p. 2642 - 2650 (2020/04/22)
Supported palladium-gold alloy-catalyzed cross-coupling of aryl chlorides and hydrosilanes enabled the selective formation of aryl-silicon bonds. Whereas a monometallic palladium catalyst predominantly promoted the hydrodechlorination of aryl chlorides and gold nanoparticles showed no catalytic activity, gold-rich palladium-gold alloy nanoparticles efficiently catalyzed the title reaction to give arylsilanes with high selectivity. A wide array of aryl chlorides and hydrosilanes participated in the heterogeneously-catalyzed reaction to furnish the corresponding arylsilanes in 34–80% yields. A detailed mechanistic investigation revealed that palladium and gold atoms on the surface of alloy nanoparticles independently functioned as active sites for the formation of aryl nucleophiles and silyl electrophiles, respectively, which indicates that palladium and gold atoms on alloy nanoparticles work together to enable the selective formation of aryl-silicon bonds. (Figure presented.).
Nickel/copper-cocatalyzed decarbonylative silylation of acyl fluorides
Wang, Xiu,Wang, Zhenhua,Nishihara, Yasushi
, p. 10507 - 10510 (2019/09/06)
Ni/Cu-cocatalyzed decarbonylative silylation of acyl fluorides with silylboranes has been developed to afford various arylsilanes with high efficiency and good functional-group compatibility via carbon-fluorine bond cleavage and carbon-silicon bond formation. Such transformation can not only extend the functionalization type of acyl fluorides but complement the synthetic route for arylsilanes.