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Prospects for a local detection of dark matter with future missions to Uranus and Neptune

Zwick, Lorenz; Soyuer, Deniz; Bucko, Jozef (2022). Prospects for a local detection of dark matter with future missions to Uranus and Neptune. Astronomy and Astrophysics, 664:A188.

Abstract

Aims. We investigate the possibility of detecting the gravitational influence of dark matter (DM) on the trajectory of prospective Doppler-ranging missions to Uranus and Neptune. In addition, we estimate the constraints such a mission can provide on modified and massive gravity theories via extra-precession measurements using orbiters around the ice giants.
Methods. We employed Monte Carlo-Markov chain methods to reconstruct fictitious spacecraft trajectories in a simplified solar system model with varying amounts of DM. We characterise the noise on the Doppler link by the Allan deviation σ$_{A}$, scaled on the Cassini-era value of σ$^{A}$$^{Cass}$ = 3 × 10$^{−15}$. Additionally, we compare the precision of prospective extra-precession measurements of Uranus and Neptune with the expected rates from simulations in the context of modifications to the inverse square law.
Results. We estimate that the prospective mission will be sensitive to DM densities of the order of ρ$_{DM}$ ∼ 9 × 10$^{−20}$(σ$_{A}$/σ$_{A}$$^{Cass}$) kg m$^{−3}$, while the 1σ bound on the expected galactic density of ρ$_{DM}$ ∼ 5 × 10$^{−22}$ kg m$^{−3}$ decreases as 1.0 × 10$^{−20}$(σ$_{A}$/σ$_{A}$$^{Cass}$)$^{0.8}$ kg m$^{−3}$. An improvement of two to three orders of magnitude from the baseline Allan deviation would guarantee a local detection of DM. Only a moderate reduction in ranging noise is required to rule out Milgrom’s interpolating function with solar system based observations, and improve constraints the graviton mass beyond current local-based or gravitational wave-based measurements. Our analysis also highlights the potential of future ranging missions to improve measurements of the standard gravitational parameters in the solar system.
Conclusions. We believe that a ranging mission to Uranus and Neptune also presents a unique opportunity for non-planetary science. The noise improvements required to guarantee a local detection of dark matter in the early 2040s are realistic, provided they become one of the priorities during mission development.

Additional indexing

Item Type:Journal Article, refereed, original work
Communities & Collections:07 Faculty of Science > Institute for Computational Science
Dewey Decimal Classification:530 Physics
Scopus Subject Areas:Physical Sciences > Astronomy and Astrophysics
Physical Sciences > Space and Planetary Science
Uncontrolled Keywords:Space and Planetary Science, Astronomy and Astrophysics
Language:English
Date:1 August 2022
Deposited On:07 Feb 2023 17:11
Last Modified:29 Aug 2024 01:35
Publisher:EDP Sciences
ISSN:0004-6361
OA Status:Hybrid
Free access at:Publisher DOI. An embargo period may apply.
Publisher DOI:https://doi.org/10.1051/0004-6361/202243741
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  • Language: English
  • Licence: Creative Commons: Attribution 4.0 International (CC BY 4.0)

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