13910-16-2Relevant articles and documents
-
Molinari,H. et al.
, p. 3920 - 3927 (1979)
-
Triphenylsulfonium Salts as Effective Phase Transfer Catalysts under Alkaline Conditions
Kondo, Shuji,Takeda, Yuji,Tsuda, Kazuichi
, p. 862 - 864 (1989)
Triphenylsulfonium salts work as effective phase transfer catalysts for nucleophilic substitution reactions on alkyl halides (e.g. 1) and addition reaction of dichlorocarbene to cyclohexene (8) under strongly alkaline conditions.
Convenient Synthesis of Organic Sulfides Using Impregnated Reagents
Czech, Bronislaw,Quici, Silvio,Regen, Steven L.
, p. 113 (1980)
-
A General Approach to Deboronative Radical Chain Reactions with Pinacol Alkylboronic Esters
André-Joyaux, Emy,Kuzovlev, Andrey,Renaud, Philippe,Tappin, Nicholas D. C.
, p. 13859 - 13864 (2020/06/10)
The generation of carbon-centered radicals from air-sensitive organoboron compounds through nucleohomolytic substitution at boron is a general method to generate non-functionalized and functionalized radicals. Due to their reduced Lewis acidity, alkylboronic pinacol esters are not suitable substrates. We report their in situ conversion into alkylboronic catechol esters by boron-transesterification with a substoichiometric amount of catechol methyl borate combined with an array of radical chain processes. This simple one-pot radical-chain deboronative method enables the conversion of pinacol boronic esters into iodides, bromides, chlorides, and thioethers. The process is also suitable the formation of nitriles and allylated compounds through C?C bond formation using sulfonyl radical traps. The power of combining radical and classical boron chemistry is illustrated with a modular 5-membered ring formation using a combination of three-component coupling and protodeboronative cyclization.
Nickel-Catalyzed Inter- and Intramolecular Aryl Thioether Metathesis by Reversible Arylation
Delcaillau, Tristan,Bismuto, Alessandro,Lian, Zhong,Morandi, Bill
supporting information, p. 2110 - 2114 (2019/12/24)
A nickel-catalyzed aryl thioether metathesis has been developed to access high-value thioethers. 1,2-Bis(dicyclohexylphosphino)ethane (dcype) is essential to promote this highly functional-group-tolerant reaction. Furthermore, synthetically challenging macrocycles could be obtained in good yield in an unusual example of ring-closing metathesis that does not involve alkene bonds. In-depth organometallic studies support a reversible Ni0/NiII pathway to product formation. Overall, this work not only provides a more sustainable alternative to previous catalytic systems based on Pd, but also presents new applications and mechanistic information that are highly relevant to the further development and application of unusual single-bond metathesis reactions.