Detecting gravitational signatures of dark matter with atom gradiometers
-
1.
California Institute of Technology
-
2.
University of California, Berkeley
-
3.
University of California, San Diego
-
4.
Johns Hopkins University
Abstract
We study the purely gravitational signatures of dark matter from the ultralight to the ultraheavy mass range in proposed long-baseline atom gradiometers, focusing on terrestrial designs, such as AION-km and MAGIS-km, as well as space-based concepts, such as MAGIS-space, AEDGE and AEDGE+. Due to its exceptional acceleration sensitivity and depending on astrophysical backgrounds, a detector similar to AEDGE+ could detect a dark matter subcomponent which constitutes 𝒪(10%) of the local dark matter energy density and is populated by compact clumps of mass between 10⁶ kg and 10¹⁰ kg (10⁻²⁵𝑀⊙ ≲ 𝑀 ≲10⁻²¹𝑀⊙) in an otherwise unexplored region of dark matter model space. Furthermore, because the gravitational observable depends on the relative gravitational time delay measured by spatially separated atomic clouds, we find that atom gradiometers are parametrically more sensitive than laser interferometers, such as LIGO and LISA, to fast-oscillating spacetime perturbations sourced by energy density and pressure fluctuations of ultralight dark matter. Depending on astrophysical backgrounds, a detector akin to AEDGE+ could probe a DM overdensity of 𝒪(10) times the local dark matter energy density for masses 𝑚 ≲10⁻¹⁷ eV.
Copyright and License
Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI. Funded by SCOAP3.
Acknowledgement
L. B. would like to thank Marek Lewicki and Ville Vaskonen for helpful discussions on the impact of astrophysical foregrounds on the projected reach of space-based AG proposals, and Federico Cima for carefully reading the manuscript. L. B., Y. D., V. L., Y. W. and K. Z. are supported by the U.S. Department of Energy, Office of Science, Office of High Energy Physics under Award No. DE-SC0011632, and by the Walter Burke Institute for Theoretical Physics. V. L. is supported by NSF Physics Frontier Center Award No. 2020275 and the Heising-Simons Foundation. Y. W. is also supported by Grant No. 147323 Award No. 704089 from Fermi National Accelerator Laboratory. KZ is also supported by a Simons Investigator award, and by Heising-Simons Foundation “Observational Signatures of Quantum Gravity” collaboration Grant No. 2021-2817. The computations presented here were conducted in the Resnick High Performance Computing Center, a facility supported by Resnick Sustainability Institute at the California Institute of Technology.
Data Availability
The data are not publicly available. The data are available from the authors upon reasonable request.
Files
| Name | Size | Download all |
|---|---|---|
|
md5:4df36fa6ffb23be00c6c0a117167ac16
|
868.3 kB | Preview Download |
Additional details
- United States Department of Energy
- DE-SC0011632
- California Institute of Technology
- Walter Burke Institute for Theoretical Physics -
- National Science Foundation
- 2020275
- Heising-Simons Foundation
- 2021-2817
- Fermi National Accelerator Laboratory
- 147323
- Fermi National Accelerator Laboratory
- 704089
- Resnick Sustainability Institute
- Accepted
-
2025-08-07
- Caltech groups
- Walter Burke Institute for Theoretical Physics, Division of Physics, Mathematics and Astronomy (PMA)
- Publication Status
- Published