Nonequilibrium dynamics in an optical transition from a neutral quantum dot to a correlated many-body state

TL;DR

This study explores how many-body interactions influence the optical absorption spectrum of a charge-tunable quantum dot coupled to an electron gas, revealing a tunable impurity regime with Fermi-edge singularities.

Contribution

We extend the Anderson impurity model to include a static hole and dynamic scattering, providing new insights into Fermi-edge physics in quantum dots.

Findings

Good agreement between experiment and renormalization group theory

Constructive Fano interference enhances Fermi-edge singularity visibility

Quantum dot acts as a tunable impurity enabling dynamic Fermi-edge studies

Abstract

We investigate the effect of many-body interactions on the optical absorption spectrum of a charge-tunable quantum dot coupled to a degenerate electron gas. A constructive Fano interference between an indirect path, associated with an intra dot exciton generation followed by tunneling, and a direct path, associated with the ionization of a valence-band quantum dot electron, ensures the visibility of the ensuing Fermi-edge singularity despite weak absorption strength. We find good agreement between experiment and renormalization group theory, but only when we generalize the Anderson impurity model to include a static hole and a dynamic dot-electron scattering potential. The latter highlights the fact that an optically active dot acts as a tunable quantum impurity, enabling the investigation of a new dynamic regime of Fermi-edge physics.