| Abstract
| - This study explored the effect of radical size, chain length, and mass on the radical cage effect.Radical cage pairs of the type [(RCp)(CO)3M•, •M(CO)3(CpR)] (M = Mo or W; CpR = various substitutedcyclopentadienyl ligands) were generated by photolysis (λ = 540 nm) of the metal−metal bonds in(RCp)2M2(CO)6. The cage recombination efficiencies (denoted as FcP) for the radical cage pairs were obtainedby extracting them from quantum yield measurements for the photoreactions with CCl4 (a metal-radical trap)as a function of solvent system viscosity. For the series of molecules (R3SiOCH2CH2Cp)2Mo2(CO)6 (R = Me,i-Pr, n-Pr, n-Hx), the FcP values were linearly proportional to mass1/2/radius2, in agreement with the predictionsof Noyes' cage effect theory. It is also demonstrated that the difference in the cage recombination efficienciesbetween the [(MeCp)(CO)3Mo•, •Mo(CO)3(CpMe)] and [(MeCp)(CO)3W•, •W(CO)3(CpMe)] cage pairs cannotbe ascribed to the different masses of the radicals. Rather, the difference is shown to be attributable to differencesin the metal−metal bond energies or to differences in the spin−orbit coupling. In another comparison, FcP atany viscosity for [(MeCp)(CO)3Mo•, •Mo(CO)3(CpMe)] was shown to be identical to that of [Cp*(CO)3Mo•,•Mo(CO)3Cp*] (Cp* = η5-C5Me5) in tetrahydrofuran (THF)/tetraglyme solution. Rotation of the MeCp ringis fast compared to the time scale of diffusive separation (kdP) and radical recombination (kcP), and hence theeffective volumes of the radicals in the solvent cage are nearly identical, which leads to similar FcP values.
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