Distinguishing antiferromagnetic spin sublattices via the spin Seebeck effect

TL;DR

This paper demonstrates a novel electrical detection method using the spin Seebeck effect to distinguish and track individual magnetic sublattices in uniaxial antiferromagnets, advancing spintronic characterization techniques.

Contribution

It introduces the use of spin Seebeck effect for independent detection of antiferromagnetic sublattices, overcoming limitations of previous magnetoresistance-based methods.

Findings

Spin Seebeck signals reflect surface sublattice moments.

The method distinguishes antiparallel antiferromagnetic states.

Interface spin sublattices generate measurable voltages.

Abstract

Antiferromagnets are beneficial for future spintronic applications due to their zero magnetic moment and ultrafast dynamics. But gaining direct access to their antiferromagnetic order and identifying the properties of individual magnetic sublattices, especially in thin films and small-scale devices, remains a formidable challenge. So far, the existing read-out techniques such as anisotropic magnetoresistance, tunneling anisotropic magnetoresistance, and spin-Hall magnetoresistance, are even functions of sublattice magnetization and thus allow us to detect different orientations of the N\'eel order for antiferromagnets with multiple easy axes. In contrast direct electrical detection of oppositely oriented spin states along the same easy axes (e.g., in uniaxial antiferromagnets) requires sensitivity to the direction of individual sublattices and thus is more difficult. In this study, using spin Seebeck effect, we report the electrical detection of the two sublattices in a uniaxial antiferromagnet Cr2O3. We find the rotational symmetry and hysteresis behavior of the spin Seebeck signals measured at the top and bottom surface reflect the dierction of the surface sublattice moments, but not the N\'eel order or the net moment in the bulk. Our results demonstrate the important role of interface spin sublattices in generating the spin Seebeck voltages, which provide a way to access each sublattice independently, enables us to track the full rotation of the magnetic sublattice, and distinguish different and antiparallel antiferromagnetic states in uniaxial antiferromagnets.