Quadrupolar and dipolar excitons in symmetric trilayer heterostructures: Insights from first principles theory

TL;DR

This study uses first principles calculations to explore how symmetric trilayer heterostructures exhibit quadrupolar and dipolar excitons with distinct Stark shift behaviors under electric fields, revealing the coupling mechanisms and stability of these excitons.

Contribution

It provides new insights into the formation and behavior of quadrupolar and dipolar excitons in symmetric trilayer heterostructures under electric fields, based on first principles theory.

Findings

Quadratic Stark shift at low fields for interlayer excitons.

Linear Stark shift at higher fields due to exciton coupling.

Quadrupolar excitons form at small fields and are sensitive to tunneling effects.

Abstract

Excitons in van der Waals heterostructures come in many different forms. In bilayer structures, the electron and hole may be localized on the same layer or they may be separated forming an interlayer exciton with a finite out-of-plane dipole moment. Using first principles calculations, we investigate the excitons in a symmetric WS$_2$/MoS$_2$/WS$_2$ heterostructure in the presence of a vertical electric field. The excitons exhibit a quadratic Stark shift for low field strengths and a linear Stark shift for stronger fields. This behaviour is traced to the coupling of interlayer excitons with opposite dipole moments, which lead to the formation of quadrupolar excitons at small fields. The formation of quadrupolar excitons is determined by the relative size of the electric field-induced splitting of the dipolar excitons and the coupling between them given by the hole tunneling across the MoS$_2$ layer. For the inverted structure, MoS$_2$/WS$_2$/MoS$_2$, the dipolar excitons are coupled by electron tunneling across the WS$_2$ layer. Because this effect is much weaker, the resulting quadrupolar excitons are more fragile and break at a weaker electric field.