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Intrinsic Nonlinear Hall Effect in Antiferromagnetic Tetragonal CuMnAs

Chong Wang, Yang Gao, Di Xiao

2021Physical Review Letters227 citationsDOIOpen Access PDF

Abstract

Detecting the orientation of the Néel vector is a major research topic in antiferromagnetic spintronics. Here we recognize the intrinsic nonlinear Hall effect, which is independent of the relaxation time, as a prominent contribution to the time-reversal-odd second order conductivity and can be used to detect the reversal of the Néel vector. In contrast, the Berry-curvature-dipole-induced nonlinear Hall effect depends linearly on relaxation time and is time-reversal even. We study the intrinsic nonlinear Hall effect in an antiferromagnetic metal: tetragonal CuMnAs, and show that its nonlinear Hall conductivity can reach the order of mA/V^{2}. The dependence on the chemical potential of such nonlinear Hall conductivity can be qualitatively explained by a tilted massive Dirac model. Moreover, we demonstrate its strong temperature dependence and briefly discuss its competition with the second order Drude conductivity. Finally, a complete survey of magnetic point groups is presented, providing guidelines for finding more antiferromagnetic materials with the intrinsic nonlinear Hall effect.

Topics & Concepts

Condensed matter physicsAntiferromagnetismHall effectNonlinear systemTetragonal crystal systemPhysicsQuantum Hall effectThermal Hall effectRelaxation (psychology)Magnetic fieldElectrical resistivity and conductivityHall conductivityConductivityMaterials scienceOrder (exchange)Weak localizationMagnetoresistanceAnisotropyDirac (video compression format)Orientation (vector space)Topological Materials and PhenomenaMagnetic properties of thin filmsChemical and Physical Properties of Materials
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