TRANSLATIONAL DIFFUSION CONSTANTS AND INTERMOLECULAR RELAXATION IN PARAMAGNETIC SOLUTIONS WITH HYPERFINE COUPLING ON THE ELECTRONIC SITE

We investigate the NMR relaxation of solvent nuclei in non viscous par amagnetic solutions, in the case where the electronic spin of the para magnetic species is submitted to an internal hyperfine field H-hyp. Ge neral expressions of the intermolecular longitudinal relaxation rates 1/T-1 are provided, and three distinct regimes corresponding to an app lied external field lower, larger and much larger than H-hyp appear, w ith three distinct linear laws for the relaxation rate 1/T-1 vs v(1)(1 /2) ,, where vl is the nuclear resonance frequency. From each of these laws and mainly the third one, it is possible to derive the relative diffusion constant of the paramagnetic and solvent molecules without a ny model assumption for solutions with a rather high radical concentra tion of 10(-1) mol L-1. This is illustrated for a triglyme solution wi th new stable (NTMIOD)-N-15 free radicals at various concentrations. F or this solution, T-1 measurements were performed at v(1) = 244 MHz, t hen at low and intermediate frequencies by the field cycling technique and finally in the Earth's magnetic field. From these results and fro m measurements of the solvent molecule diffusion constant by the pulse d magnetic field gradient technique, a determination of the diffusion constant of the free radicals is obtained which is compared with that obtained from a direct ESR measurement at low concentration. These dat a are used for the interpretation of the frequency and temperature dep endence of the relaxation rates in this solution.