Spatio-temporal equilibrium thermodynamics of guided optical waves at positive and negative temperatures
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Abstract
Optical thermalization has been recently studied in the 2D spatial evolution of (quasi-)monochromatic light waves propagating in multimode waveguides.
Here, we investigate the spatio-temporal equilibrium properties of optical waves through the analysis of the (2+1)D Bose-Einstein thermal distribution and the corresponding classical Rayleigh-Jeans approximation.
Numerical simulations of the nonlinear Schrödinger equation (NLSE) demonstrate relaxation toward the spatio-temporal Rayleigh-Jeans equilibrium state, as described by the corresponding wave turbulence kinetic equation.
Remarkable adiabatic cooling phenomena stemming from the high-frequency tails of the Rayleigh-Jeans distribution are discussed and the consequent limitations of the classical approximation are highlighted.
To overcome these issues, we make use of a quantum version of the NLSE whose associated kinetic equation describes relaxation toward the spatio-temporal Bose-Einstein equilibrium distribution.
The analysis of thermodynamic properties reveals a strong dependence on the dispersion regime.
In the anomalous dispersion regime, the system relaxes to positive-temperatures equilibrium states: as the number of modes of the waveguide increases, the fundamental spatial mode becomes macroscopically populated, while its temporal spectrum undergoes significant narrowing, ultimately leading to complete (2+1)D spatio-temporal condensation in the thermodynamic limit.
In the normal dispersion regime, the system evolves toward negative-temperature equilibrium states characterized by an inverted spatial modal population.
In this regime, we predict a phase transition to Bose-Einstein condensation at negative temperatures, which occurs by increasing the temperature above a negative critical value.
Our work opens new avenues for future research and lay the groundwork for the development of spatiotemporal optical thermodynamics.