First principles studies of 2D transition metal dichalcogenides on 3D magnetic oxides

Monolayer transition metal dichalcogenides are desirable for new high-speed, low-power and miniaturized valley optoelectronics. One way to create valley polarization is via magnetic proximity coupling, facilitated by interfacing single-layer TMDs and magnetic substrates; this approach has recently been shown to generate significantly larger valley splitting than applied magnetic fields. However, the reported valley splitting is still relatively small and the details of the interface between TMDs and magnetic substrates are poorly understood. Using first principles and model calculations, we explore the structure of the TMD-oxide interface, and predict the magnitude of the valley splitting generated by proximity to magnetic substrates. We examine the most critical attributes of this interface and develop general design principles that connect the structure of TMD-oxide interfaces to functionality relevant for valleytronics.