Electronic Correlations Control Interlayer Coupling and Magnetic Transition in MnBi2Te4/MnBr3 Heterostructure

Abstract

Bulk MnBi2Te4 (MBT) is an intrinsic antiferromagnetic topological insulator. However, its low N\'eel temperature of 25\,K severely restricts its practical applications. Here, we propose a van der Waals heterostructure composed of monolayer MBT (ML-MBT) and monolayer MnBr3, an intrinsic Chern insulator possessing a high Curie temperature (TC 200\,K). By employing density functional theory calculations and Monte Carlo simulations, we demonstrate that interfacing ML-MBT with MnBr3 significantly enhances the TC of ML-MBT by a factor of four to five. Electronic correlations characterized by the Hubbard parameter U2 for Mn-d orbitals in MnBr3 play a crucial role in governing magnetic coupling within the system. At a moderate correlation strength of U2 = 3.0\,eV, slight structural distortions in MnBr3 break intralayer symmetry, enabling robust interlayer ferromagnetic coupling and yielding a single, unified magnetic transition. Increasing U2 reduces these structural distortions, weakens interlayer coupling, and induces two distinct magnetic transitions, indicating interlayer magnetic decoupling. Thus, the MBT/MnBr3 heterostructure offers a novel approach for controlling magnetic order and enhancing the performance of spintronic devices.