Spin-Valley-Mismatched Altermagnet for Giant Tunneling Magnetoresistance

Abstract

Altermagnet-based heterojunctions have demonstrated magnetoresistive effects in experiments, however, a predictive theoretical model for non-ferromagnetic structures has remained elusive. In this work, we develop a tunneling-based spin-transport theory that explicitly incorporates the transverse-wavevector (k\|)-dependent spin polarization of an altermagnet's transport channels, enabling the prediction of giant tunneling magnetoresistance (TMR). Based on the theory, we predict that the altermagnet KV2Se2O can reach the extreme limit of magnetoresistance. By performing first-principles transport calculations, we verify that magnetic tunnel junctions using the metallic KV2Se2O as the electrodes and few-layer MgO as the spacer exhibit zero-bias magnetoresistance larger than 7.57×107\%, which is robust against the bias and thickness of the spacer. Our research provides a quantitative design principle for next-generation spin-electronic devices and establishes KV2Se2O/MgO/KV2Se2O as a leading candidate material system for room-temperature ultra-high-density non-volatile memory.