Spin and thermal transport and critical phenomena in three-dimensional antiferromagnets

Abstract

We investigate spin and thermal transport near the N\'eel transition temperature TN in three dimensions, by numerically analyzing the classical antiferromagnetic XXZ model on the cubic lattice, where in the model, the anisotropy of the exchange interaction =Jz/Jx plays a role to control the universality class of the transition. It is found by means of the hybrid Monte-Carlo and spin-dynamics simulations that in the XY and Heisenberg cases of ≤ 1, the longitudinal spin conductivity σsμμ exhibits a divergent enhancement on cooling toward TN, while not in the Ising case of >1. In all the three cases, the temperature dependence of the thermal conductivity μμ is featureless at TN, being consistent with experimental results. The divergent enhancement of σsμμ toward TN is attributed to the spin-current relaxation time which gets longer toward TN, showing a power-law divergence characteristic of critical phenomena. It is also found that in contrast to the XY case where the divergence in σsμμ is rapidly suppressed below TN, σsμμ likely remains divergent even below TN in the Heisenberg case, which might experimentally be observed in the ideally isotropic antiferromagnet RbMnF3.