Litcius/Paper detail

Many-body theory of the optical conductivity of excitons and trions in two-dimensional materials

Farhan Rana, Okan Koksal, Christina Manolatou

2020Physical review. B./Physical review. B48 citationsDOIOpen Access PDF

Abstract

The optical spectra of two-dimensional (2D) materials exhibit sharp absorption peaks that are commonly identified with exciton and trions (or charged excitons). In this paper, we show that excitons and trions in doped 2D materials can be described by two coupled Schr\"odinger-like equations---one two-body equation for excitons and another four-body equation for trions. In electron-doped 2D materials, a bound trion state is identified with a four-body bound state of an exciton and an excited conduction-band electron-hole pair. In doped 2D materials, the exciton and trion states are the not the eigenstates of the full Hamiltonian and their respective Schr\"odinger equations are coupled due to Coulomb interactions. The strength of this coupling increases with the doping density. Solutions of these two coupled equations can quantitatively explain all the prominent features experimentally observed in the optical absorption spectra of 2D materials, including the observation of two prominent absorption peaks and the variation of their energy splittings and spectral shapes and strengths with the electron density. The optical conductivity obtained in our paper satisfies the optical conductivity sum rule exactly. A superposition of exciton and trion states can be used to construct a solution of the two coupled Schr\"odinger equations and this solution resembles the variational exciton-polaron state, thereby establishing the relationship between our approach and Fermi polaron physics.

Topics & Concepts

TrionExcitonPolaronPhysicsCondensed matter physicsSchrödinger equationOptical conductivityExcited stateBiexcitonElectronHamiltonian (control theory)Fermi's golden ruleBinding energyAtomic physicsQuantum mechanicsFermi Gamma-ray Space TelescopeMathematicsMathematical optimization2D Materials and ApplicationsPerovskite Materials and ApplicationsTopological Materials and Phenomena