1122-70-9Relevant articles and documents
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Wentrup
, p. 1386 (1969)
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An Electroreductive Approach to Radical Silylation via the Activation of Strong Si-Cl Bond
Lu, Lingxiang,Siu, Juno C.,Lai, Yihuan,Lin, Song
supporting information, p. 21272 - 21278 (2020/12/21)
The construction of C(sp3)-Si bonds is important in synthetic, medicinal, and materials chemistry. In this context, reactions mediated by silyl radicals have become increasingly attractive but methods for accessing these intermediates remain limited. We present a new strategy for silyl radical generation via electroreduction of readily available chlorosilanes. At highly biased potentials, electrochemistry grants access to silyl radicals through energetically uphill reductive cleavage of strong Si-Cl bonds. This strategy proved to be general in various alkene silylation reactions including disilylation, hydrosilylation, and allylic silylation under simple and transition-metal-free conditions.
Radical Hydroarylation of Functionalized Olefins and Mechanistic Investigation of Photocatalytic Pyridyl Radical Reactions
Seath, Ciaran P.,Vogt, David B.,Xu, Zihao,Boyington, Allyson J.,Jui, Nathan T.
supporting information, p. 15525 - 15534 (2018/11/23)
We report the photoredox alkylation of halopyridines using functionalized alkene and alkyne building blocks. Selective single-electron reduction of the halogenated pyridines provides the corresponding heteroaryl radicals, which undergo anti-Markovnikov addition to the alkene substrates. The system is shown to be mild and tolerant of a variety of alkene and alkyne subtypes. A combination of computational and experimental studies support a mechanism involving proton-coupled electron transfer followed by medium-dependent alkene addition and rapid hydrogen atom transfer mediated by a polarity-reversal catalyst.