Linear and nonlinear optical response based on many-body GW-Bethe-Salpeter and Kadanoff-Baym approaches for two-dimensional layered semiconductors

TL;DR

This paper presents advanced many-body calculations of linear and nonlinear optical responses in 2D layered semiconductors, revealing how excitonic effects and material properties influence optical behaviors like SHG, THG, and HHG.

Contribution

It develops a comprehensive theoretical framework for predicting nonlinear optical responses in 2D semiconductors using GW-Bethe-Salpeter and Kadanoff-Baym methods, incorporating excitonic effects.

Findings

Dark excitons dominate in 2D monolayers, bright in 3D bulk materials.

Larger atomic mass and reduced detuning enhance nonlinear responses.

General formulas for nonlinear optical response based on exciton states are derived.

Abstract

The family of 2D layered semiconductors, including transition metal chalcogenides (TMCs) of the form MX (M=Ga, In; X=S, Se, Te) exhibit exceptional nonlinear optical properties. The energetically most favorable crystal ordering for nonlinear response is the AB layer stacking, which breaks central inversion symmetry for an arbitrary number of layers, resulting in non-zero off-diagonal elements of the $\chi^{(2n')}$ tensor, $n'$ being a positive integer, for arbitrary thickness of the materials. We perform first-principles many-body calculations of bandstructures and linear and nonlinear optical responses of monolayer (ML) and bulk TMC crystals based on $GW$-Bethe-Salpeter and Kadanoff-Baym approaches in and out of equilibrium, respectively, while taking many-body band gap renormalization and excitonic effects into account. We develop a detailed analysis of the linear and nonlinear optical selection rules by means of group and representation theory. We observe the general trend that the lowest-energy excitons are dark in 2D ML TMCs whereas they are bright or mixed bright-dark in 3D bulk TMCs, which we attribute to the difference between spatially dependent screening in 2D and constant screening in 3D. In particular, we derive general formulas for the nonlinear optical response based on exciton states in semiconductor materials. We find anti-bound excitons in ML GaS, which we attribute to dominant exciton exchange interaction. We show that by choosing elements with larger mass and by reducing the detuning energy it is possible to increase the nonlinear response not only for $\chi^{(2)}$ and $\chi^{(3)}$, responsible for SHG and third harmonic generation (THG), but also in general for $\chi^{(n)}$ nonlinear response with $n>3$, giving rise to high harmonic generation (HHG) in 2D semiconductor materials.