1313709-36-2Relevant articles and documents
A Simplified Protocol for the Stereospecific Nickel-Catalyzed C-S Vinylation Using NiX 2 Salts and Alkyl Phosphites
Larin, Egor M.,Lautens, Mark,Marchese, Austin D.,Mirabi, Bijan
, p. 311 - 319 (2019/12/28)
A Ni-catalyzed C-S cross-coupling using only NiI 2 (0.5-2.5 molpercent) and P(O i Pr) 3 (2.0-10.0 molpercent) is reported. Using an air-stable Ni(II) precatalyst, and a cheap and commercially available ligand, a scalable and robust method was developed to cross-couple various thiophenols and styryl bromides, including some sterically encumbered thiols, an α-bromocinnamaldehyde as well as a thiolation-cyclization.
Safe and Metal-Free Synthesis of 1-Alkenyl Aryl Sulfides and Their Sulfones from Thiiranes and Diaryliodonium Salts
Dong, Jun,Xu, Jiaxi
, p. 2407 - 2415 (2018/04/16)
A series of 1-alkenyl aryl sulfides was synthesized from thiiranes and diaryliodonium salts in tetrahydrofuran in the presence of potassium tert -butoxide. The proposed reaction mechanism involves generation of benzynes from the diaryliodonium salts in the presence of the base. Then, nucleophilic attack of the benzynes by thiiranes, followed by hydrogen abstraction and ring opening of the generated thiiranium intermediates, provides the sulfides. These sulfides were further oxidized with performic acid to the corresponding sulfones. The current method provides a metal-free and safe method for the preparation of 1-alkenyl aryl sulfides and their sulfones.
Cobalt modified N-doped carbon nanotubes for catalytic C=C bond formation via dehydrogenative coupling of benzyl alcohols and DMSO
Li, Jinlei,Liu, Guoliang,Shi, Lijun,Xing, Qi,Li, Fuwei
supporting information, p. 5782 - 5788 (2017/12/26)
The development of heterogeneous, cost-effective and environmentally benign catalysts to construct C=C bonds is highly desirable. We report here Co@N-doped carbon nanotubes (Co@NCNT) as a catalyst for a novel synthesis of styryl sulfides via dehydrogenative coupling of benzyl alcohols and DMSO under anaerobic conditions. This reaction maintains high atom efficiency as the C=C bond is formed without the cracking of the C-S bond. We proposed that Co modified N-doped carbon sites are the active sites, different from traditionally believed metal centers for dehydrogenative C-C coupling. Moreover, the Co@NCNT catalyst could be easily separated and recycled for at least six runs. This work opens up a new application of metal-N-C catalysts in C=C bond-forming reactions in synthetic chemistry.