Maciej Pieczarka, Marcin Gębski, Aleksandra N. Piasecka, James A. Lott, Axel Pelster, Michał Wasiak, Tomasz Czyszanowski:
🔓 arXiv:2307.00081 (2023)
Many bosons can occupy a single quantum state without a limit, which is described by quantum-mechanical Bose-Einstein statistics and allows the formation of a Bose-Einstein condensate at low temperatures and high particle densities. Photons, historically the first considered bosonic gas, were among the last to show this phenomenon, which was observed in rhodamine-filled microlaser cavities or doped fiber cavities. These more recent findings have raised the natural question as to whether condensation is common in laser systems, potentially implying its technological application. Here, we show the Bose-Einstein condensation of photons in a semiconductor vertical-cavity surface-emitting laser with positive cavity-gain energy detuning. We observed a Bose-Einstein condensate in the ground mode at the critical phase-space density. Experimental results follow the equation of state for a two-dimensional gas of bosons in thermal equilibrium, although the extracted spectral temperatures were lower than those of the device. This is interpreted as originating from the driven-dissipative nature of the condensate being not in full thermal equilibrium with the device. In contrast, non-equilibrium lasing action is observed in higher-order modes in a negatively detuned device. Our work enables the potential exploration of superfluid physics of interacting photons mediated by semiconductor optical non-linearities. It also shows great promise for single-mode high-power emission from a large aperture device.