A tabletop quantum optics system with phase-controlled biphoton sources is mapped onto the Unruh-DeWitt model to emulate detector transitions driven by vacuum fluctuations and to study coherence harvesting.
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Back-action from Unruh-DeWitt detectors produces energy fluxes that exactly account for detector transitions due to the Unruh effect, including negative energy density regions near the Rindler horizon and in the far future for ground-state accelerated detectors.
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Quantum Optical Simulator for Unruh-DeWitt Detector Dynamics
A tabletop quantum optics system with phase-controlled biphoton sources is mapped onto the Unruh-DeWitt model to emulate detector transitions driven by vacuum fluctuations and to study coherence harvesting.
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Back-action from inertial and non-inertial Unruh-DeWitt detectors revisited in covariant perturbation theory
Back-action from Unruh-DeWitt detectors produces energy fluxes that exactly account for detector transitions due to the Unruh effect, including negative energy density regions near the Rindler horizon and in the far future for ground-state accelerated detectors.