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Observation of Light Thermalization to Negative-Temperature Rayleigh-Jeans Equilibrium States in Multimode Optical Fibers

K. Baudin, Josselin Garnier, Adrien Fusaro, Nicolas Berti, C. Michel, Katarzyna Krupa, G. Millot, Antonio Picozzi

2023Physical Review Letters48 citationsDOIOpen Access PDF

Abstract

Although the temperature of a thermodynamic system is usually believed to be a positive quantity, under particular conditions, negative-temperature equilibrium states are also possible. Negative-temperature equilibriums have been observed with spin systems, cold atoms in optical lattices, and two-dimensional quantum superfluids. Here we report the observation of Rayleigh-Jeans thermalization of light waves to negative-temperature equilibrium states. The optical wave relaxes to the equilibrium state through its propagation in a multimode optical fiber-i.e., in a conservative Hamiltonian system. The bounded energy spectrum of the optical fiber enables negative-temperature equilibriums with high energy levels (high-order fiber modes) more populated than low energy levels (low-order modes). Our experiments show that negative-temperature speckle beams are featured, in average, by a nonmonotonic radial intensity profile. The experimental results are in quantitative agreement with the Rayleigh-Jeans theory without free parameters. Bringing negative temperatures to the field of optics opens the door to the investigation of fundamental issues of negative-temperature states in a flexible experimental environment.

Topics & Concepts

Rayleigh scatteringPhysicsThermalisationMulti-mode optical fiberOptical latticeThermodynamic equilibriumHamiltonian (control theory)Optical fiberOpticsQuantum mechanicsSuperfluidityMathematicsMathematical optimizationAdvanced Fiber Laser TechnologiesMechanical and Optical ResonatorsStrong Light-Matter Interactions
Observation of Light Thermalization to Negative-Temperature Rayleigh-Jeans Equilibrium States in Multimode Optical Fibers | Litcius