Pieczarka, Maciej
Bose-Einstein condensation of light in a vertical-cavity-surface-emitting laser
Maciej Pieczarka - Department of Experimental Physics, Wrocław University of Science and Technology, Poland
Photons were the first bosons to be considered under the quantum statistics known today as the Bose-Einstein statistics. However, they were one of the last quantum gases to undergo Bose-Einstein condensation in a controlled environment, achieved in a microcavity filled with a rhodamine solution [1]. On one hand, since these pioneering observations, the principle of light thermalization and condensation in optical cavities has been anticipated to be a much more common phenomenon occurring in other systems. On the other hand, the Bose-Einstein condensation contrasts with the common understanding of laser operation being a nonequilibrium phenomenon.
In this talk, I will present our results on the Bose-Einstein condensation of photons in a well-established semiconductor device, the vertical-cavity surface-emitting laser (VCSEL) [2]. Firstly, I will introduce the physics behind light thermalization and condensation in semiconductor laser cavities [3]. Next, I will present our measurements of a Bose-Einstein condensation behavior when crossing the critical phase-space density and the observation of a thermalized distribution of photons in the condensate. The observed spectroscopic and thermodynamic properties show all predicted effects for a Bose-Einstein condensate phase transition in thermal equilibrium. Moreover, I will discuss the local properties of inhomogeneous photons in broad-area devices. Our results offer a new view on the working principles of semiconductor lasers and have great potential for technological development for future laser devices [4].
References
[1] J. Klaers et al., Nature 468, 545–548 (2010)
[2] M. Pieczarka et al., Nature Photonics 18, 1090–1096 (2024)
[3] A. Loirette-Pelous, & J.-J. Greffet, Laser Photonics Rev., 17, 2300366. (2023)
[4] A. Fainstein & G. Usaj, Nature Photonics 18, 999–1001 (2024)