Observation of the Anomalous Hall Effect in a Layered Polar Semiconductor

Progress in magnetoelectric materials is hindered by apparently contradictory requirements for time-reversal symmetry broken and polar ferroelectric electronic structure in common ferromagnets and antiferromagnets. Alternative routes can be provided by recent discoveries of a time-reversal symmetry breaking anomalous Hall effect (AHE) in noncollinear magnets and altermagnets, but hitherto reported bulk materials are not polar. Here, the authors report the observation of a spontaneous AHE in doped AgCrSe2, a layered polar semiconductor with an antiferromagnetic coupling between Cr spins in adjacent layers. The anomalous Hall resistivity 3 mu omega cm$\mu \Omega \, \textnormal {cm}$ is comparable to the largest observed in compensated magnetic systems to date, and is rapidly switched off when the angle of an applied magnetic field is rotated to approximate to 80 degrees from the crystalline c-axis. The ionic gating experiments show that the anomalous Hall conductivity magnitude can be enhanced by modulating the p-type carrier density. They also present theoretical results that suggest the AHE is driven by Berry curvature due to noncollinear antiferromagnetic correlations among Cr spins, which are consistent with the previously suggested magnetic ordering in AgCrSe2. The results open the possibility to study the interplay of magnetic and ferroelectric-like responses in this fascinating class of materials. A spontaneous anomalous Hall effect is observed in a layered polar semiconductor, and, remarkably, the magnitude of the anomalous Hall conductivity can be enhanced by tuning the carrier density employing ionic-gated transistors. Theoretical calculations, considering the magnetic order and polar nature, align well with experimental observations. The findings shed new light on exploring the interplay between magnetic and polar structures.image

Automated summary

A spontaneous anomalous Hall effect is observed in a layered polar semiconductor, and remarkably, the magnitude of the anomalous Hall conductivity can be enhanced by tuning the carrier density employing ionic-gated transistors. Theoretical calculations, considering the magnetic order and polar nature, align well with experimental observations. The findings shed new light on exploring the interplay between magnetic and polar structures.