Fourier transform electron spin echo envelope modulation of a S=1/2, I=5/2 spin system: An exact analysis and a second order perturbation approach

Abstract

Electron spin echo envelope modulation (ESEEM) induced by ²⁷Al nuclei can be used to characterize the interactions of paramagnetic transition metal cations with the framework of various aluminosilicates. The quantitative analysis of such systems is complex due to the ²⁷Al nuclear quadrupole interaction which is often large and unknown. In order to obtain a better understanding of the various spectral features of the ²⁷Al modulation, the ESEEM of a S= (1)/(2) I= (5)/(2) spin system in orientationally disordered systems was investigated in the frequency domain. The relative contributions of the various electron‐nuclear double resonance (ENDOR) frequencies to the Fourier transform (FT) ESEEM spectrum were studied as a function of the size of the nuclear quadrupole coupling constant and of the relative orientation of the nuclear quadrupole tensor with respect to the g‐tensor. The parameters range investigated is that expected from Cu²⁺ interacting with framework Al in zeolites. Two approaches were employed in the calculations, exact diagonalization of the nuclear Hamiltonian and a second order perturbation treatment of the quadrupole interaction. It is found that the second order perturbation approach applies up to e²qQ/h<7 MHz. The conditions under which the FT‐ESEEM spectrum is dominated by the ‖ (1)/(2) 〉−‖− (1)/(2) 〉 <named-content xmlns:mml="http://www.w3.org/1998/Math/MathML"...