Ld. Slep et al., SYNTHESIS AND ELECTRONIC-STRUCTURE OF PENTACYANOOSMATE(II) COMPLEXES WITH N-HETEROCYCLIC LIGANDS, Inorganic chemistry, 35(21), 1996, pp. 6327-6333
The series of complexes [Os-II(CN)(5)L](n-), with L = pyridine or pyra
zine derivatives, were prepared in aqueous solution and, in some cases
, as sodium or potassium salts. The main feature in the UV-visible spe
ctra is the appearance of an intense, asymmetric MLCT band, split unde
r spin-orbit coupling. The energies and intensities of the MLCT bands
decrease and increase, respectively, with the electron-acceptor abilit
y of L, and strong solvatochromic energy shifts are observed in differ
ent organic media. The Os(II) complexes can be oxidized chemically or
electrochemically to the Os(III) species; the latter show typical LMCT
bands in the visible region, independent of L. The redox potentials f
or the Os-III,Os-II couples (range 0.6-1.0 V (NHE)), shift positively
when L becomes more electron-withdrawing or less basic. Reduction pote
ntials for the bound and free Mepz(+) ligand showed similar values, ca
. -0.53 V (NHE), for the three [M(CN)(5)L](n-) complexes, suggesting s
imilar back-bonding abilities of Fe, Ru, and Os toward a given L ligan
d; this is confirmed by the linear plots with unit slope obtained for
the energy of the MLCT bands of the [M(CN)(5)L](n-) complexes (M = Fe,
Ru) against the values for the [Os(CN)(5)L](n-) complexes. The IR spe
ctra show intense and weak bands at ca. 2050 and 2100 cm(-1), associat
ed with equatorial and axial cyanide stretchings, respectively. The di
ssociation rate constant for pyrazine release from the [Os(CN)(5)pz](3
-) ion shows a saturation kinetic behavior, typical of dissociative me
chanisms found for the iron and ruthenium analog complexes; the specif
ic dissociation rate constant, k(-pz) = 2.0 x 10(-8) s(-1) (25 degrees
C, I = 0.5 M), is about 3 and 4 orders of magnitude slower than the v
alues found for [Ru(CN)(5)pz](3-) and [Fe(CN)(5)pz](3-), respectively;
this is ascribed mainly to the strong a interaction in the Os-L bond.