Bosonic statistics enhance Maxwell's demon in photonic experiment
- URL: http://arxiv.org/abs/2602.11276v1
- Date: Wed, 11 Feb 2026 19:00:05 GMT
- Title: Bosonic statistics enhance Maxwell's demon in photonic experiment
- Authors: Malaquias Correa Anguita, Sara Marzban, William F. Braasch, Twesh Upadhyaya, Gabriel Landi, Nicole Yunger Halpern, Jelmer J. Renema,
- Abstract summary: Maxwell's demon elucidates the value of information in thermodynamics using measurement and feedback.<n>We experimentally support this decade-and-a-half-old prediction by comparing indistinguishable with distinguishable photons.<n>This work suggests a thermodynamic means of weakly validating boson-sampling platforms.
- Score: 0.28106259549258145
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Maxwell's demon elucidates the value of information in thermodynamics, using measurement and feedback: he evolves an equilibrated gas into a nonequilibrium state, from which one might extract work. The demon can evolve the system farther from equilibrium, on average, if the particles obey Bose-Einstein statistics than if they are distinguishable. We experimentally support this decade-and-a-half-old prediction by comparing indistinguishable with distinguishable photons. We use a fully programmable linear-optics platform, whose local photon statistics were shown recently to behave thermally. Our demon nondestructively measures the number of photons in a subset of the modes. Guided by the outcome, he conditionally interchanges the measured and unmeasured modes. This interchange creates a positive temperature difference between a mode in a particular subset and a mode in the other. The temperature difference is greater, on average, if the photons are indistinguishable. This result bolsters a long-standing prediction about the interplay among thermodynamics, information, and quantum particle statistics. Additionally, this work suggests a thermodynamic means of weakly validating boson-sampling platforms.
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