Enze Zhang1,2†, Zi-Ting Sun3†, Zehao Jia1,2†, Jinshan Yang4†, Jingyi Yan4, Linfeng Ai1,2, Ying-Ming Xie3, Yuda Zhang1,2, Xue-Jian Gao3, Xian Xu5, Shanshan Liu1,2, Qiang Ma1,2, Chaowei Hu6, Xufeng Kou7, Jin Zou8,9,10, Ni Ni6, Kam Tuen Law3*, Shaoming Dong4, Faxian Xiu1,2,11,12
Science Advances
14 May 2025
Vol 11, Issue 20
Abstract
Hybridizing
superconductivity with topology and magnetism attracts growing interest
in condensed matter physics. Here, we present our findings on the
measurement of supercurrent induced in an intrinsic antiferromagnetic
topological insulator MnBi2Te4. By constructing a MnBi2Te4
proximity Josephson junction, we observed an anomalously large period
of the Fraunhofer patterns, indicating a strong Josephson coupling
state. As the MnBi2Te4 thickness is reduced, a
distinct asymmetric edge supercurrent emerges, aligning consistently
with the observed oscillatory junction magnetoresistance. Leveraging
this large asymmetric edge supercurrent, we have realized a nonvolatile
Josephson diode device with programmable polarity, achieved through
training with an out-of-plane magnetic field. Theoretical calculations
substantiate that these behaviors are attributed to the interference
between the highly asymmetric topological edge channel–mediated
supercurrent induced in MnBi2Te4. Our study
establishes this system as a promising avenue for investigating
topological superconductivity, chiral Majorana edge modes, and advanced
functionality device applications.
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