Thermality, causality and the quantum-controlled Unruh-deWitt detector
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Particle detector models such as the Unruh-deWitt detector are widely used in relativistic quantum information and field theory to probe the global features of spacetime and quantum fields. These detectors are typically modelled as coupling locally to the field along a classical worldline. In this paper, we utilize a recent framework which enables us to prepare the detector in a quantum-controlled superposition of trajectories, and study its response to the field in finite-temperature Minkowski spacetime and an expanding de Sitter universe. Unlike a detector on a classical path which cannot distinguish these spacetimes, the superposed detector can do so by acquiring nonlocal information about the geometric and causal structure of its environment, demonstrating its capability as a probe of these global properties.
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Cited by 2 Pith papers
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Testing Superpositions of Detector Trajectories
Proposes an optical beamsplitter setup with a BEC to make the response function of a superposed Unruh-DeWitt detector appear in the difference photocurrent power spectrum, with SNR greater than or equal to 10 using sq...
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Testing Superpositions of Detector Trajectories
Proposes using split laser beams on a pancake BEC and heterodyning to make the response function of a superposed Unruh-deWitt detector appear in the difference photocurrent power spectrum, with SNR estimates using squ...
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