Radical reactions McMurry coupling

Catalytic turn-over [59,60] in McMurry couplings [61], Nozaki-Hiyama reactions [62,63], and pinacol couplings [64,65] has been reported by Fiirst-ner and by Hirao by in situ silylation of titanium, chromium and vanadium oxo species with McaSiCl. In the epoxide-opening reactions, protonation can be employed for mediating catalytic turn-over instead of silylation because the intermediate radicals are stable toward protic conditions. The amount of Cp2TiCl needed for achieving isolated yields similar to the stoichiometric process can be reduced to 1-10 mol% by using 2,4,6-collidine hydrochloride or 2,6-lutidine hydrochloride as the acid and Zn or Mn dust as the reduc-tant (Scheme 9) [66,67]. 

Titanium compounds are used very frequently in organic synthesis, however, often stoichiometrically [8]. [Cp2TiCl]2 is the most frequently applied titanium reagent to mediate radical reactions (reviews [123, 124]). Radicals are also often invoked in McMurry couplings mediated by low-valent titanium species (reviews [125-127]) and in the related pinacol coupling (reviews [128-130]). 

Intramolecular free radical cyclization of dicarboxylic esters leads to a-hydroxy ketones (acyloins). Reductive coupling of dicarbonyl compounds provides 1,2-diols ipinacols) and further reaction of these yields cycloalkenes (McMurry reaction). These cyclization reactions are especially valuable for the preparation of medium and large rings that are not readily accessible by other methods. 

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