M. Aizenberg et al., METAL-DEPENDENT STABILIZATION OF SI-S BONDS TO HYDROLYSIS IN IRIDIUM AND RHODIUM SILYLS - HYDROLYZABILITY AS A PROBE FOR SI-H REDUCTIVE ELIMINATION, Organometallics, 15(3), 1996, pp. 1075-1078
The iridium (triethylthio)silyl complexes cis-(PPh(3))(2)(CO)IrH2(Si(S
Et)(3)) (5), fac-(PMe(3))(3)Ir(CH3)(H)-(Si(SEt)(3) (6), and mer-(PMe(3
))(3)Ir(C6F5)(H)(Si(SEt)(3)) (7) were synthesized by oxidative additio
n, of HSi(SEt)(3) (1) to HIr(CO)(PPh(3))(3) (2), CH(3)IrPMe(3))(4) (3)
, and C6F5 Ir(PMe(3))(3) (4), respectively. 4 was synthesized by the r
eaction between Ir(PMe(3))(4)Cl and C6F5MgBr. The rhodium analog of 7,
mer-(PMe(3))(3)Rh(C6F5)(H)(Si(SEt)(3)) (9), was obtained similarly fr
om C6F5Rh(PMe(3))(3), (8) and 1. Unlike the extremely easily hydrolyza
ble parent silane 1, compounds 5-7 are stable in H2O/THF and even in N
aOH/H2O/THF solutions. This stabilization is attributed to the electro
n-donating capacity of the Ir centers, which efficiently reduces elect
rophilicity of the silicon. Reactivity of the rhodium complex 9 is str
ikingly different, cleanly producing in the presence of 5 equiv of H2O
the ethylthio-complex mer-(PMe(3))(3)Rh(C6F5)(H)(SEt) (10). Compound
10 was identified spectroscopically and was synthesized independently
from 8 and HSEt. A plausible scheme accounting for the generation of 1
0 under the hydrolysis conditions is presented. The observed differenc
e in the reactivities of 5-7 and 9 is explained in terms of their diff
erent tendencies to reductively eliminate H-Si(SEt)(3).