Spin-Atomic Vibration Interaction and Spin-Flip Hamiltonian of a Single Atomic Spin in a Crystal Field

Abstract

We derive the spin-atomic vibration interaction V SA and the spin-flip Hamiltonian V SF of a single atomic spin in a crystal field. We here apply the perturbation theory to a model with the spin-orbit interaction and the kinetic and potential energies of electrons. The model also takes into account the difference in vibration displacement between an effective nucleus and electrons, r. Examining the coefficients of V SA and V SF, we first show that V SA appears for r0, while V SF is present independently of r. As an application, we next obtain V SA and V SF of an Fe ion in a crystal field of tetragonal symmetry. It is found that the magnitudes of the coefficients of V SA can be larger than those of the conventional spin-phonon interaction depending on vibration frequency. In addition, transition probabilities per unit time due to V SA and V SF are investigated for the Fe ion with an anisotropy energy of -|D|SZ2, where D is an anisotropy constant and SZ is the Z component of a spin operator.