Novel excitonic states and photoluminescence in quantum hall systems

TL;DR

This paper explores the formation, decay, and photoluminescence of various excitonic complexes in quantum Hall systems, revealing new bound states and decay mechanisms in strongly magnetic 2D electron systems.

Contribution

It introduces novel excitonic states such as fractionally charged anyon excitons and discusses their decay processes in quantum Hall regimes.

Findings

Identification of new excitonic bound states in quantum Hall systems

Analysis of decay mechanisms including radiative recombination

Implications for nuclear spin relaxation processes

Abstract

The formation and possible decay processes of neutral and charged excitonic complexes in electronic integral and fractional quantum Hall systems are discussed. The excitonic complexes are bound states of a small number of the relevant negatively and positively charged quasiparticles (e.g., conduction electrons and valence holes, reversed-spin electrons and spin holes, Laughlin quasielectrons and quasiholes, composite Fermions) that can occur in a 2D electron in the presence of a strong magnetic field. Examples of such bound states are interband neutral and charged excitons, fractionally charged "anyon excitons", spin waves, skyrmions, or "skyrmion excitons". Possible decay processes include radiative recombination, experimentally observed in photoluminescence or spin transitions, important in the context of nuclear spin relaxation.