The unidirectional Seebeck detection of the N\'eel vector in the two-dimensional tetragonal PT-symmetric antiferromagnetic materials

Abstract

The efficient detection of the reversal (180 rotation) of the N\'eel vector is one of the crucial tasks in antiferromagnetic spintronics. Here, we propose a thermal approach to detect the reversal of the N\'eel vector in the tetragonal PT antiferromagnetic materials through the unidirectional Seebeck effect (USE). Being different from the previous works in which USE stems from the global Rashba spin-orbit coupling (SOC) or asymmetric magnon scattering, we find that the USE originates from the coupling of the hidden Rashba SOC and the N\'eel vector in the tetragonal PT antiferromagnetic materials in the absence of the global Rashba SOC. Using a generic minimal model, we analyse the behaviors of the USE for the two-dimensional tetragonal lattice PT antiferromagnet. Importantly, It's found that when the N\'eel vector is reversed, the sign of the USE changes, which can be utilized to detect the reversal of the N\'eel vector.