6533b862fe1ef96bd12c6db2
RESEARCH PRODUCT
Observation of the Anomalous Hall Effect in a Collinear Antiferromagnet
Zexin FengXiaorong ZhouLibor ŠMejkalLei WuZengwei ZhuHuixin GuoRafael González-hernándezXiaoning WangHan YanPeixin QinXin ZhangHaojiang WuHongyu ChenZhengcai XiaChengbao JiangMichael CoeyJairo SinovaTomáš JungwirthZhiqi Liusubject
Condensed Matter::Materials ScienceCondensed Matter - Materials ScienceCondensed Matter - Strongly Correlated ElectronsQuantum PhysicsStrongly Correlated Electrons (cond-mat.str-el)Condensed Matter - Mesoscale and Nanoscale PhysicsMesoscale and Nanoscale Physics (cond-mat.mes-hall)Materials Science (cond-mat.mtrl-sci)FOS: Physical sciencesApplied Physics (physics.app-ph)Physics - Applied PhysicsQuantum Physics (quant-ph)description
Time-reversal symmetry breaking is the basic physics concept underpinning many magnetic topological phenomena such as the anomalous Hall effect (AHE) and its quantized variant. The AHE has been primarily accompanied by a ferromagnetic dipole moment, which hinders the topological quantum states and limits data density in memory devices, or by a delicate noncollinear magnetic order with strong spin decoherence, both limiting their applicability. A potential breakthrough is the recent theoretical prediction of the AHE arising from collinear antiferromagnetism in an anisotropic crystal environment. This new mechanism does not require magnetic dipolar or noncollinear fields. However, it has not been experimentally observed to date. Here we demonstrate this unconventional mechanism by measuring the AHE in an epilayer of a rutile collinear antiferromagnet RuO$_2$. The observed anomalous Hall conductivity is large, exceeding 300 S/cm, and is in agreement with the Berry phase topological transport contribution. Our results open a new unexplored chapter of time-reversal symmetry breaking phenomena in the abundant class of collinear antiferromagnetic materials.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-02-20 |