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Main Authors: Di Pumpo, Fabio, Friedrich, Alexander, Giese, Enno
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2309.04207
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author Di Pumpo, Fabio
Friedrich, Alexander
Giese, Enno
author_facet Di Pumpo, Fabio
Friedrich, Alexander
Giese, Enno
contents Several terrestrial detectors for gravitational waves and dark matter based on long-baseline atom interferometry are currently in the final planning stages or already under construction. These upcoming vertical sensors are inherently subject to gravity and thus feature gradiometer or multi-gradiometer configurations using single-photon transitions for large momentum transfer. While there has been significant progress on optimizing these experiments against detrimental noise sources and for deployment at their projected sites, finding optimal configurations that make the best use of the available resources are still an open issue. Even more, the fundamental limit of the device's sensitivity is still missing. Here we fill this gap and show that (a) resonant-mode detectors based on multi-diamond fountain gradiometers achieve the optimal, shot-noise limited, sensitivity if their height constitutes 20% of the available baseline; (b) this limit is independent of the dark-matter oscillation frequency; and (c) doubling the baseline decreases the ultimate measurement uncertainty by approximately 65%. Moreover, we propose a multi-diamond scheme with less mirror pulses where the leading-order gravitational phase contribution is suppressed, compare it to established geometries, and demonstrate that both configurations saturate the same fundamental limit.
format Preprint
id arxiv_https___arxiv_org_abs_2309_04207
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Optimal baseline exploitation in vertical dark-matter detectors based on atom interferometry
Di Pumpo, Fabio
Friedrich, Alexander
Giese, Enno
Quantum Physics
General Relativity and Quantum Cosmology
Several terrestrial detectors for gravitational waves and dark matter based on long-baseline atom interferometry are currently in the final planning stages or already under construction. These upcoming vertical sensors are inherently subject to gravity and thus feature gradiometer or multi-gradiometer configurations using single-photon transitions for large momentum transfer. While there has been significant progress on optimizing these experiments against detrimental noise sources and for deployment at their projected sites, finding optimal configurations that make the best use of the available resources are still an open issue. Even more, the fundamental limit of the device's sensitivity is still missing. Here we fill this gap and show that (a) resonant-mode detectors based on multi-diamond fountain gradiometers achieve the optimal, shot-noise limited, sensitivity if their height constitutes 20% of the available baseline; (b) this limit is independent of the dark-matter oscillation frequency; and (c) doubling the baseline decreases the ultimate measurement uncertainty by approximately 65%. Moreover, we propose a multi-diamond scheme with less mirror pulses where the leading-order gravitational phase contribution is suppressed, compare it to established geometries, and demonstrate that both configurations saturate the same fundamental limit.
title Optimal baseline exploitation in vertical dark-matter detectors based on atom interferometry
topic Quantum Physics
General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2309.04207