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Macroscopic Dark Matter Detection with Gravitational Wave Experiments

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arxiv 2306.13122 v2 pith:XFGDSI7Z submitted 2023-06-22 astro-ph.CO gr-qchep-ph

Macroscopic Dark Matter Detection with Gravitational Wave Experiments

classification astro-ph.CO gr-qchep-ph
keywords experimentsgravitationaldarkeffectfindforceinterferometersmacroscopic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We study signatures of macroscopic dark matter (DM) in current and future gravitational wave (GW) experiments. Transiting DM with a mass of $\sim10^5-10^{15}$ kg that saturates the local DM density can be potentially detectable by GW detectors, depending on the baseline of the detector and the strength of the force mediating the interaction. In the context of laser interferometers, we derive the gauge invariant observable due to a transiting DM, including the Shapiro effect (gravitational time delay accumulated during the photon propagation), and adequately account for the finite photon travel time within an interferometer arm. In particular, we find that the Shapiro effect can be dominant for short-baseline interferometers such as Holometer and GQuEST. We also find that proposed experiments such as Cosmic Explorer and Einstein Telescope can constrain a fifth force between DM and baryons, at the level of strength $\sim 10^3$ times stronger than gravity for, e.g., kg mass DM with a fifth-force range of $10^6$ m.

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Cited by 1 Pith paper

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