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Quantum Algorithms
Contrast Loss from Astrophysical Backgrounds in Space-Based Matter-Wave Interferometers
arXiv
Authors: Yufeng Du, Clara Murgui, Kris Pardo, Yikun Wang, Kathryn M. Zurek
Year
2023
Paper ID
56070
Status
Preprint
Abstract Read
~2 min
Abstract Words
132
Citations
N/A
Abstract
Atom and matter interferometers are precise quantum sensing experiments that can probe differential forces along separated spacetime paths. Various atom and matter interferometer experiments have been proposed to study dark matter, gravitational waves, and exotic new physics. Increasingly, these experimental concepts have proposed space-based designs to maximize interrogation times and baselines. However, decoherence and phase shifts caused by astrophysical backgrounds could largely undermine or destroy the target sensitivity of the experiments. We calculate the decoherence effects induced by solar photons, the solar wind, cosmic rays, solar neutrinos and zodiacal dust on space-based atom and matter interferometers. We find that, in future space-based atom and matter interferometers, the solar wind generically produces decoherence beyond the quantum noise limit, without proper shielding. In addition, solar photons are also an important background for matter interferometers.
Why This Paper Matters
- It adds a 2023 reference point for readers tracking recent quantum research.
- Atom and matter interferometers are precise quantum sensing experiments that can probe differential forces along separated spacetime paths.
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