32609-88-4Relevant academic research and scientific papers
Transition-Metal Silyl Complexes, 32. - Anionic Silyl Complexes as Equivalents to Dianionic Metal Complexes in Synthesis: Reactions of (1-) with Main-Group 5 Dihalides
Kirchgaessner, Uwe,Schubert, Ulrich
, p. 1481 - 1482 (2007/10/02)
The versatility of anionic silyl complexes for preparative purposes is demonstrated by reactions with dihalides of phosphorus, arsenic, and antimony in their +III and +V oxidation states.Na (1) reacts with Ph3AsCl2 or Ph3SbBr2 to give (MeCp)(CO)2Mn(EPh3) (2a: E = Sb, 2b: E = As), while reaction with MesPCl2 (Mes = 2,4,6-Me3C6H2) affords the binuclear compound >(MeCp)(CO)2Mn>2PMes (3).Both reactions proceed by Ph2MeSiX elimination. - Keywords: Anionic metal complexes / Chlorosilane elimination / Phosphinidene complexes / Silyl complexes
ELECTRON TRANSFER AND TRANSIENT RADICALS IN ORGANOMETALLIC CHEMISTRY
Kochi, Jay K.
, p. 139 - 166 (2007/10/02)
The variety of reactions available with metal carbonyls, both as mononuclear species and polynuclear clusters, is used to underscore the importance of electron transfer, transient radicals and ion radicals in organometallic chemistry.
Kinetics, Thermodynamics, and Mechanism of the Radical Chain Process for Ligand Substitution of Metal Carbonyls
Hershberger, J. W.,Klingler, R. J.,Kochi, J. K.
, p. 61 - 73 (2007/10/02)
The radical chain process for the ligand substitution of a variety of carbonylmanganese derivatives (MnL) can be induced chemically or electrochemically with turnover numbers that can exceed 103.The catalytic cycle is initiated by electron transfer to afford the 17-electron carbonylmanganese cation MnL+.The propagation steps in the chain process are (1) the facile ligand exchange of MnL+ with the added nucleophile L to afford MnL+ followed by (2) the reduction of MnL+ by a homogeneous process involving cross electron exchange with MnL and/or heterogeneous electron transfer at the electrode.This carbonylmetal system is sufficiently well-behaved to allow the kinetics and thermodynamics for each step of the catalytic cycle to be examined in quantitative detail by transient and bulk electrochemical techniques.Analysis of the reversible cyclic voltammograms of MnL, both in the presence and in the absence of the nucleophile L, is achieved by Feldberg's digital simulation method.The computer simulation of the experimental cyclic voltammograms provides accurate values of the second-order rate constants for the rapid ligand exchange of MnL+ with a variety of added nucleophiles L.The unusual reactivity patterns for substitution in the paramagnetic MnL are presented in the context of previous studies with other metal carbonyls.
