Microscopic theory of excitons bound by light

TL;DR

This paper develops a theoretical framework to understand exciton polaritons in semiconductor microcavities where Coulomb binding is absent, revealing photon-mediated binding mechanisms and matching experimental observations.

Contribution

It introduces a diagrammatic theory to analyze photon-mediated exciton binding and spectral response in microcavities without Coulomb-bound excitons, highlighting conditions for photon-induced binding.

Findings

Photon exchange can bind excitons in microcavities without Coulomb interactions.

Coulomb interactions can enhance exciton binding at high photon frequencies.

The spectral response matches recent experimental results.

Abstract

We theoretically investigate the scenario of a semiconductor quantum well in a microcavity, where the band structure is arranged such that optically excited electron-hole pairs cannot form Coulomb-bound excitonic states. However, it is still possible to form exciton polaritons (part-light, part-matter quasiparticles), where the excitons are bound via the exchange of microcavity photons rather than via Coulomb interactions. Using a diagrammatic theory, we determine the spectral response of the semiconductor microcavity, which includes exciton-polariton resonances as well as a continuum of unbound electron-hole pairs. Our method also gives us access to the photon fraction and the electron-hole wave function of the exciton polariton. In particular, we obtain the conditions under which an exciton is bound by photon exchange and we show that Coulomb interactions can enhance binding at large cavity photon frequencies. Our results for the spectral response are in good agreement with a recent experiment on doped quantum wells [E. Cortese et al., Nat. Phys. 17, 31 (2021)].