Title: Synthesis of main group, rare-earth, and d{sup 0} metal complexes containing beta-hydrogen

A series of organometallic compounds containing the tris(dimethylsilyl)methyl ligand are described. The potassium carbanions KC(SiHMe₂)₃ and KC(SiHMe₂})₃TMEDA are synthesized by deprotonation of the hydrocarbon HC(SiHMe₂)₃ with potassium benzyl. KC(SiHMe₂)₃TMEDA crystallizes as a dimer with two types of three-center-two-electron KH- Si interactions. Homoleptic Ln(III) tris(silylalkyl) complexes containing β-SiH groups M{C(SiHMe₂)₃}₃ (Ln = Y, Lu, La) are synthesized from salt elimination of the corresponding lanthanide halide and 3 equiv. of KC(SiHMe₂)₃. The related reactions with Sc yield bis(silylalkyl) ate-complexes containing either LiCl or KCl. The divalent calcium and ytterbium compounds M{C(SiHMe₂)₃}₂L (M = Ca, Yb; L = THF₂ or TMEDA) are prepared from MI₂ and 2 equiv of KC(SiHMe₂)₃. The compounds M{C(SiHMe₂)₃}₂L (M = Ca, Yb; L = THF₂ or TMEDA) and La{C(SiHMe₂)₃}₃ react with 1 equiv of B(C₆F₅)₃ to give 1,3- disilacyclobutane {Me2Si-C(SiHMe2)2}2 and MC(SiHMe2)3HB(C6F5)3L, and La{C(SiHMe₂)₃}₂HB(C₆F₅)₃, respectively. The corresponding reactions of Ln{C(SiHMe₂)₃}₃ (Ln = Y, Lu) give the β-SiH abstraction product [{(Me₂HSi)₃C}₂LnC(SiHMe₂)₂SiMe₂][HB(C₆F₅)₃] (Ln = Y, Lu), but the silene remains associated with the Y or Lu center. The abstraction reactions of M{C(SiHMe₂)₃}₂L (M = Ca, Yb; L = THF₂or TMEDA) and Ln{C(SiHMe₂)₃}₃ (Ln = Y, Lu, La) and 2 equiv of B(C₆F₅)₃ give the expected dicationic M{HB(C₆F₅)₃}₂L (M = Ca, Yb; L = THF₂ or TMEDA) and dicationic mono(silylalkyl) LnC(SiHMe₂)₃{HB(C₆F₅)₃}₂ (Ln = Y, Lu, La), respectively. Salt metathesis reactions of Cp₂(NR₂)ZrX (X = Cl, I, OTf; R = t-Bu, SiHMe₂) and lithium hydrosilazide ultimately afford hydride products Cp₂(NR₂)ZrH that suggest unusual β-hydrogen elimination processes. A likely intermediate in one of these reactions, Cp₂Zr[N(SiHMe₂)t-Bu][N(SiHMe₂)₂], is isolated under controlled synthetic conditions. Addition of alkali metal salts to this zirconium hydrosilazide compound produces the corresponding zirconium hydride. However as conditions are varied, a number of other pathways are also accessible, including C-H/Si-H dehydrocoupling, γ-abstraction of a CH, and β-abstraction of a SiH. Our observations suggest that the conversion of (hydrosilazido)zirconocene to zirconium hydride does not follow the classical four-center β- elimination mechanism.