Simulation of Strain Effects in EPR Spectra

Strain-induced line broadening is often observed in EPR spectra. This line broadening is due to distortions in the local structure around the radical center resulting in a distribution of spin Hamiltonian parameters. The X-band EPR spectrum of Rhenium(VI) in the polyoxoanion, [P₂ReW₁₇O₆₂]^-6, shown in the top figure , shows remarkable changes in linewidth. The linewidth varies from 25 Gauss at lowest fields to more than 120 Gauss at highest fields. Clearly for this rhenium system, the linewidth is nearly completely dominated by strain effects, and simple M_I and M_I² dependant linewidth expressions are deemed inappropriate for a spectrum which is not first-order. As can be seen our simulation reproduces extremely well both the line positions and linewidths in the EPR spectrum. The two peaks marked with asterisks are "forbidden" m_I = 5/2 to 3/2 and m_I = 3/2 to 5/2 transitions. The spacing between these two peaks is direct measure of the nuclear quadrupole coupling constant and is equal to 8QD/g_eff. The lower figure, which compares the simulation with and without the strain broadening, demonstrates graphically the marked field dependence of the strain-induced line-broadening. This linewidth variation can be readily ascribed to random strains or distortions of the rhenium ion complex with a resultant distribution of spin Hamiltonian parameters, particularly in the g-tensor. Strain parameters were determined not only for g and A, but also for the nuclear quadrupole tensor, which is a direct measure of the change in electric field gradients at the metal nucleus due to strain. Simulation and fitting of electron paramagnetic resonance spectra used the automated simulation program SIMPIPM which is a special version of SIMPIP that includes strain-broadening. The spin Hamiltonian

= {ßBgS - ß_ng_nBI} + hSAI + hIPI + hSDS

is solved by exact diagonalization, followed by a fourth-order field-frequency perturbation to transform the energy spectrum into a field-swept spectrum. The spin Hamiltonian parameters are varied using the SIMPLEX method to minimize the RMS deviation between experimental and calculated spectra. Strain effects were included by calculating exact analytical gradients of the eigenvalues of the spin Hamiltonian. The fourth-order frequency perturbation (was used to transform the frequency-swept spectrum to a field sweep one and is also used applied to the calculation of the analytical gradients.

Last Updated on March 27, 2002 by M. Nilges