Spontaneous coherence in spatially extended photonic systems: Non-Equilibrium Bose-Einstein condensation

TL;DR

This review discusses the universal phenomena of Bose-Einstein condensation in various driven-dissipative photonic systems, emphasizing non-equilibrium effects on coherence and dynamics, and explores future scientific and technological prospects.

Contribution

It provides an interdisciplinary overview highlighting the universal non-equilibrium phenomena in photonic Bose-Einstein condensates across diverse systems.

Findings

Identification of universal non-equilibrium phenomena affecting coherence

Analysis of static and dynamic properties of photon condensates

Discussion of future applications in science and technology

Abstract

In this review, we give an interdisciplinary overview of Bose-Einstein condensation phenomena in photonic systems. We cover a wide range of systems, from lasers to photon condensates in dye-filled cavities, to excitons in semiconductor heterostructures, to microcavity polaritons, as well as emerging systems such as mode-locked lasers and classical light waves. Rather than diving into the specific properties of each system, our main focus will be to highlight those novel universal phenomena that stem from the driven-dissipative, non-equilibrium nature of these systems and affect the static, dynamic and coherence properties of the condensate. We conclude with our view on the future perspectives of this field for both fundamental science and technological applications.