UC Berkeley

Rare earth tris(alkyl) complexes such as M(CH2SiMe3)3(sol) n are widely used as precursors for many compounds and as homogeneous catalysts for alkene polymerization and alkane functionalization. However, the thermal instability of those most conveniently made from the commercially available lithium salt of the neosilyl anion, LiCH2SiMe3, Li(r), restricts their utility. We present a new range of synthetically useful, more kinetically stable rare earth neosilyl solvates, derived from a full kinetic study of the various possible decomposition mechanisms of 7 known and 12 new solvated rare earth neosilyl complexes M(CH2SiMe3)3(sol) n M = Sc(iii), Y(iii), Lu(iii), Sm(iii), and sol = THF; TMEDA; DMPE; diglyme ((CH3)2(OCH2CH2)2O, G2), triglyme ((CH3)2(OCH2CH2)3O, G3). Surprisingly, simply using higher-denticity donors to sterically disfavor neosilyl γ-H elimination is not effective. While Sc(r)3((CH3)2(OCH2CH2)2O) has a half-life, t 1/2, of 258.1 h, six times longer than for Sc(r)3(C4H8O)2 (t 1/2 = 43 h), Lu(r)3((CH3)2(OCH2CH2)2O) and Y(r)3((CH3)2(OCH2CH2)2O) do not show the expected, analogous increased t 1/2. This is because new decomposition pathways appear for poorly fitting donors. Finally, kinetic studies demonstrate the impact of small, and increasing amounts of LiCl on the kinetics of the reactivity of the smaller alkyls Y(r)3(THF)2 and Lu(r)3(THF)2; molecules used in hydrocarbon chemistry and catalysis for fifty years. A new route to pure Y(r)3(THF)2, which avoids the traditional use of Li(r), is presented.