D. Donges et al., INTRALIGAND CHARGE-TRANSFER IN PT(QOL)(2) - CHARACTERIZATION OF ELECTRONIC STATES BY HIGH-RESOLUTION SHPOLSKII SPECTROSCOPY, Inorganic chemistry, 36(14), 1997, pp. 3040-3048
Pt(qol)(2) (qol(-) = 8-quinolinolato-O,N) is investigated in the Shpol
'skii matrices n:heptane, n-octane-h(18), n-octane-d(18), n-nonane, an
d n-decane, respectively. For the first time, highly resolved triplet
phosphorescence as well as triplet and singlet excitation spectra are
obtained at T = 1.2 K by site-selective spectroscopy. This permits the
detailed characterization of the low-lying singlet and triplet states
which are assigned to result mainly from intraligand charge transfer
(ILCT) transitions. The electronic origin corresponding to the (ILCT)-
I-3 lies at 15 426 cm(-1) (FWHM approximate to 3 cm(-1)) exhibiting a
zero-field splitting smaller than 1 cm(-1), which shows that the metal
d-orbital contribution to the (ILCT)-I-3 is small. At T = 1.2 K, the
three triplet sublevels emit independently due to slow spin-lattice re
laxation (sir) processes. Therefore, the phosphorescence decays triexp
onentially with components of 4.5, 13, and 60 mu s. Interestingly, two
of the sublevels can be excited selectively, which leads to a distinc
t spin polarization manifested by a biexponential decay. At T = 20 K,
the decay becomes monoexponential with tau = 10 mu s due to a fast sir
between the triplet sublevels. From the Zeeman splitting of the 3ILCT
the g-factor is determined to be 2.0 as expected for a relatively pur
e spin triplet. The (ILCT)-I-1 has its electronic origin at 18 767 cm(
-1) and exhibits a homogeneous line width of about 12 cm(-1) This feat
ure allows us to estimate a singlet-cm triplet intersystem crossing ra
te of about 2 x 10(12) s(-1). This relatively large rate compared to v
alues found for closed shell metal M(qol)(n) compounds displays the im
portance of spin-orbit coupling induced by the heavy metal ion. Moreov
er, this small admixture leads to the relatively short emission decay
times. All spectra show highly resolved vibrational satellite structur
es. These patterns provide information about vibrational energies (whi
ch are in good accordance with Raman data) and shifts of equilibrium p
ositions between ground and excited states. These shifts are different
in the (ILCT)-I-1 and (ILCT)-I-3 states. The vibrational satellite st
ructures support the assignment of ILCT character to the lowest excite
d states.