Magnetic tunnel junctions (MTJs) are the key building blocks of high-performance spintronic devices. While conventional MTJs rely on ferromagnetic (FM) materials, employing antiferromagnetic (AFM) compounds can significantly increase operation speed and packing density. Current prototypes of AFM tunnel junctions (AFMTJs) exploit antiferromagnets either as spin-filter insulating barriers or as metal electrodes supporting bulk spin-dependent currents. Here, we highlight a largely overlooked AFMTJ prototype, where bulk-spin-degenerate electrodes with an A-type AFM stacking form magnetically uncompensated interfaces, enabling spin-polarized tunneling currents and a sizable tunneling magnetoresistance (TMR) effect. Using first-principles quantum-transport calculations and the van der Waals (vdW) metal Fe4GeTe2 as a representative A-type AFM electrode, we demonstrate a large negative TMR arising solely from the alignment of interfacial magnetic moments. This prototype of AFMTJs can also be realized with various non-vdW A-type AFM metals that support roughness-insensitive surface magnetization. Beyond TMR, AFMTJs based on A-type antiferromagnets allow convenient switching of the N\'eel vector, opening a new paradigm for AFM spintronics that leverages spin-dependent properties at AFM interfaces.
@article{arxiv.2506.12715,
title = {Interface-controlled antiferromagnetic tunnel junctions},
author = {Liu Yang and Yuan-Yuan Jiang and Xiao-Yan Guo and Shu-Hui Zhang and Rui-Chun Xiao and Wen-Jian Lu and Lan Wang and Yu-Ping Sun and Evgeny Y. Tsymbal and Ding-Fu Shao},
journal= {arXiv preprint arXiv:2506.12715},
year = {2025}
}