960-16-7Relevant articles and documents
Calcium stannyl formation by organostannane dehydrogenation
Morris, Louis J.,Hill, Michael S.,Manners, Ian,Mcmullin, Claire L.,Mahon, Mary F.,Rajabi, Nasir A.
supporting information, p. 12964 - 12967 (2019/11/05)
Reaction of the dimeric calcium hydride, [(BDI)CaH]2 (1), with Ph3SnH ensues with elimination of H2 to provide [(BDI)Ca-μ2-H-(SnPh3)Ca(BDI)] (3) and [(BDI)Ca(SnPh3)]2 (4) alongside dismutation to Ph4Sn, H2 and Sn(0). DFT analysis indicates that stannyl anion formation occurs through deprotonation of Ph3SnH and with retention of dinuclear species throughout the reactions.
Nickel-catalyzed decarbonylative stannylation of acyl fluorides under ligand-free conditions
Wang, Xiu,Wang, Zhenhua,Liu, Li,Asanuma, Yuya,Nishihara, Yasushi
, (2019/05/24)
Nickel-catalyzed decarbonylative stannylation of acyl fluorides under ligand-free conditions was disclosed. A variety of aromatic acyl fluorides are capable of reacting with silylstannanes in the presence of cesium fluoride. A one-pot decarbonylative stannylation/Migita-Kosugi-Stille reaction of benzoyl fluoride, giving rise to the direct formation of the corresponding cross-coupled products, further demonstrated the synthetic utility of the present method. This newly developed methodology with a good functional-group compatibility via C-F bond cleavage and C-Sn bond formation under nickel catalysis opens a new area for the functionalization of acyl fluorides in terms of carbon-heteroatom bond formation.
Method for converting substituted sodium aryl sulfonate to aryl tri-n-butyltin
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Paragraph 0039-0043; 0123-0127; 0129-0133; 0135-0139; 0141, (2018/12/14)
The invention discloses a method for converting substituted sodium acryl sulfonate to aryl tri-n-butyltin. The synthetic method of the aryl tri-n-butyltin compound comprises the following steps: uniformly mixing sodium aryl sulfonate, silver carbonate, bis(tri-tert-butylphosphine)palladium, and hexabutyldistannane in a solvent, reacting for 1 to 8 hours at 80 to 140 DEG C, and after the reaction is ended, concentrating; and performing the column chromatography, and obtaining a pure aryl tri-n-butyltin product. The adopted raw material is sodium aryl sulfonate which is significant in supplementation, wide in source, cheap and easy to obtain compared with the existing method adopting aromatic halides as a raw material. The reaction in the invention has good tolerance and universality for a functional group, and the substituent group can be hydrogen, methyl, tertiary butyl, fluorine, chlorine, bromine, cyanogroup, trifluoromethyl, nitro, acetyl or carbethoxy.