Signatures of electric field and layer separation effects on the spin-valley physics of MoSe2/WSe2 heterobilayers: from energy bands to dipolar excitons

Abstract

We investigate the spin-valley physics (SVP) in MoSe2/WSe2 heterobilayers under external electric field (EF) and changes of the interlayer distance (ID). We analyze the spin (Sz) and orbital (Lz) degrees of freedom, and the symmetry properties of relevant band edges (at K, Q, and points) in high-symmetry stackings at 0 (R-type) and 60 (H-type) degree angles, the important building blocks of moir\'e or atomically reconstructed structures. We reveal distinct hybridization signatures of Sz and Lz in low-energy bands due to the wave function mixing between the layers, which are stacking-dependent and can be further modified by EF and ID. The H-type stackings favor large changes in the g-factors under EF, e. g. from -5 to 3 in the valence bands of the Hhh stacking, due to the opposite orientation of Sz and Lz in the individual monolayers. For the low-energy dipolar excitons (DEs), direct and indirect in k-space, we quantify the electric dipole moments and polarizabilities, reflecting the layer delocalization of the constituent bands. We found that direct DEs carry a robust valley Zeeman effect nearly independent of the EF but tunable by the ID, which can be experimentally accessible via applied external pressure. For the momentum-indirect DEs, our symmetry analysis indicates that phonon-mediated optical processes can easily take place. For the indirect DEs with conduction bands at the Q point for H-type stackings, we found marked variations of the valley Zeeman ( 4) as a function of the EF that notably stand out from the other DE species. Stronger signatures of the coupled SVP are favored in H-type stackings, which can be experimentally investigated in 60o samples. Our study provides fundamental insights into the SVP of van der Waals heterostructures, relevant to understand the valley Zeeman of DEs and intralayer excitons.