posted on 2021-08-06, 14:42authored byHaifeng Lv, Yijie Niu, Xiaojun Wu, Jinlong Yang
Uncovering the physics behind the
electrical manipulation of low-dimensional
magnetic materials remains a fundamental issue in practical application
of nanoscale spintronics. Here, we propose a strategy to transform
A-type antiferromagnetic (AFM) semiconductors into asymmetric AFM
unipolar or bipolar magnetic semiconductors by applying perpendicular
electric fields in van der Waals bilayer systems. Electric fields
lifting energy levels of electrons within same spin channel from consistent
layers in opposite direction enables unipolar magnetic semiconductor,
whereas electrons within opposite spin channel enable bipolar magnetic
semiconductor. A comprehensive study demonstrates this discrepancy
originates from spatial distributions of spin density of valence band
and conduction band edges in two layers of systems. The electric field
induced unipolar or bipolar magnetic semiconducting behavior represents
great potential of nanoscale AFM spintronics for information storage
and processing.