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Quantum Thermodynamics
Superradiance and Superabsorption Engine of N Two-Level Systems: N2-Power Scaling at Near-Unity Efficiency
arXiv
Authors: L. F. Alves da Silva, H. Sanchez, M. A. Ponte, M. H. Y. Moussa, Norton G. de Almeida
Year
2025
Paper ID
51266
Status
Preprint
Abstract Read
~2 min
Abstract Words
124
Citations
N/A
Abstract
We present a thermal engine that exploits the cooperative superradiance and superabsorption of a sample of N two-level atoms. This engine operates using a single cold reservoir via cycles of collective pumping followed by decay. Using an effective mean-field Hamiltonian to describe the many-body dynamics, we design optimized drive pulses that preserve adiabaticity and achieve an average power output scaling quadratically with the system size, P propto N2. An experimentally measurable figure of merit demonstrates that the efficiency of this superengine can approach unity. The resulting analytical model, which yields a representative Hamiltonian for the sample within the mean-field formalism, is validated by numerical simulations. Our results pave the way for scalable and highly efficient quantum heat engines based on collective effects.
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- We present a thermal engine that exploits the cooperative superradiance and superabsorption of a sample of N two-level atoms.
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