EPR-Untersuchungen an elektrolytisch erzeugtem SO2

Abstract

From the triatomic molecule SO₂ with 18 valency electrons we generated the mononegative radical ion with the aid of electrolytic techniques. In this way we could vary the radical concentration over a wide range and could also study the influence of counter ions and solvent molecules. The semi-empirical LCAO-MO theory of WALSH was used to calculate the g-factor shift. UV spectroscopic data of SO₂ and Hückel-MO-calculations of the spin density distribution of the unpaired electron in the antibonding MO of SO₂ ^- resulted in Δg_theor = (3.9 ± 0.6) x 10^-3 which agrees rather well with Δg_exp = (3.414 ± 0.003) x 10^-3. The quoted error of the theoretical value refers to approximations, which have to be introduced in addition to the approximations of the LCAO-MO theory of WALSH. The HMO spin density distribution compares nicely with the distribution calculated from anisotropic hfs constants of SO₂ ^- in a KCl single crystal which have been measured recently by SCHNEIDER et al. Higher concentrations of SO₂ molecules resulted in another EPR line with Δg_exp = 4.6 x 10^-3 which we attribute to the solvated radical ion (SO₂)_xSO₂ ^-. From the temperature dependance of the concentration ratio of the radical species in we determined W = - 6.9 kcal mol^-1, x = 2, and K(0 °C) = 8.0 x 10^-5 mol² lit^-2.