Stacking-Directed Polarization and Excitonic Engineering in MoS_2/MoSe_2 van der Waals Heterostructures
Abstract
The stacking-dependent polarization and excitonic response of MoS_2/MoSe_2 heterostructures were investigated using GW+BSE many-body perturbation theory. While homobilayer MoS_2 exhibited a switchable interlayer dipole driven by registry-induced symmetry breaking, the MoS_2/MoSe_2 hetero-interface remained pinned by the intrinsic chemical potential mismatch between sulfur and selenium. In 2L-MoS_2/MoSe_2 trilayers, the stacking sequence enabled a deterministic control of photogenerated electrons between the central and bottom MoS_2 layers, governed by internal electric fields and quasiparticle band-edge shifts of 60--70~meV. Our calculations predicted a 36~meV interlayer excitonic shift, in remarkable agreement with recent experiments. These results elucidate the microscopic link between atomic registry and many-body interactions, establishing transition metal dichalcogenide trilayers as a potential platform for sliding ferroelectricity and programmable optoelectronic functionalities.
Get this paper in your agent:
hf papers read 2606.22014 Don't have the latest CLI?
curl -LsSf https://hf.co/cli/install.sh | bash Models citing this paper 0
No model linking this paper
Datasets citing this paper 0
No dataset linking this paper
Spaces citing this paper 0
No Space linking this paper
Collections including this paper 0
No Collection including this paper