Abstract

We study electron transport in monolayer molybdenum disulfide MoS2 subjected to a magnetic barrier. Our analysis employs a full-band continuum model to capture the relevant physical phenomena. We focus on how electron energy, magnetic field strength, and the geometric characteristics of the barrier affect the transmission and conductance. We observe sharp resonant tunneling features emerging from quantum interference effects induced by magnetic confinement. A key outcome of our study is the discovery of distinct resonance patterns in the conduction and valence bands. These patterns are closely related to the intrinsic spin–orbit coupling in MoS2 and the breaking of time-reversal symmetry by the magnetic field. This results in significant spin and valley selectivity in electron transport. We demonstrate that adjusting external parameters precisely controls spin-polarized and valley-polarized currents. We show that a magnetic barrier can control electron spin and valley in MoS2, making it a promising platform for energy-efficient spintronic and valleytronic devices. © 2025 Elsevier B.V.