Thermodynamics and State Preparation in a Two-State System of Light

TL;DR

This paper demonstrates thermalization and state manipulation in a two-mode photon system using an optical microcavity, providing insights into quantum thermodynamics and potential quantum technology applications.

Contribution

It presents the first experimental realization of thermalization in a two-level bosonic system with tunable chemical potential using an optical dye microcavity.

Findings

Photon thermalization observed under stationary conditions.

Population distribution follows Boltzmann statistics at low occupation.

Efficient ground state population at high filling levels.

Abstract

The coupling of two-level quantum systems to the thermal environment is a fundamental problem, with applications ranging from qubit state preparation to spin models. However, for the elementary problem of the thermodynamics of an ensemble of bosons populating a two-level system despite its conceptual simplicity experimental realizations are scarce. Using an optical dye microcavity platform, we thermalize photons in a two-mode system with tunable chemical potential, demonstrating N bosons populating a two-level system coupled to a heat bath. Under pulsed excitation, Josephson oscillations between the two quantum states demonstrate the possibility for coherent manipulation. In contrast, under stationary conditions the thermalization of the two-mode system is observed. As the energetic splitting between eigenstates is two orders of magnitude smaller than thermal energy, at low occupations an almost equal distribution of the modes occupation is observed, as expected from Boltzmann statistics. For larger occupation, we observe efficient population of the ground state and saturation of the upper level at high filling, expected from quantum statistics. Our experiment holds promise for state preparation in quantum technologies as well as for quantum thermodynamics studies.