Abstract
We consider the feasibility of testing Newtonian gravity at low accelerations using wide binary (WB) stars separated by $\ge 3$ kAU. These systems probe the accelerations at which galaxy rotation curves unexpectedly flatline, possibly due to Modified Newtonian Dynamics (MOND). We conduct Newtonian and MOND simulations of WBs covering a grid of model parameters in the system mass, semi-major axis, eccentricity and orbital plane. We self-consistently include the external field (EF) from the rest of the Galaxy on the Solar neighbourhood using an axisymmetric algorithm. For a given projected separation, WB relative velocities reach larger values in MOND. The excess is ${\approx 20\%}$ adopting its simple interpolating function, as works best with a range of Galactic and extragalactic observations. This causes noticeable MOND effects in accurate observations of ${\approx 500}$ WBs, even without radial velocity measurements. We show that the proposed Theia mission may be able to directly measure the orbital acceleration of Proxima Centauri towards the 13 kAU-distant $\alpha$ Centauri. This requires an astrometric accuracy of $\approx 1 \, \mu$as over 5 years. We also consider the long-term orbital stability of WBs with different orbital planes. As each system rotates around the Galaxy, it experiences a time-varying EF because this is directed towards the Galactic Centre. We demonstrate approximate conservation of the angular momentum component along this direction, a consequence of the WB orbit adiabatically adjusting to the much slower Galactic orbit. WBs with very little angular momentum in this direction are less stable over Gyr periods. This novel direction-dependent effect might allow for further tests of MOND.
Highlights
The currently prevailing cosmological paradigm (ΛCDM, Ostriker & Steinhardt 1995) is based on the assumption that General Relativity governs the dynamics of astrophysical systems
The effects of the non-linear Modified Newtonian Dynamics (MOND) gravity can cause a wide binary (WB) to be unstable over Gyr periods, but we find that this only affects a small proportion of WB systems in particular orientations (Section 9.2)
The wide binary test (WBT) focuses on their relative velocity v, making use of the fact that stronger gravity allows systems to be bound at a higher relative speed v ≡ |v|
Summary
The currently prevailing cosmological paradigm (ΛCDM, Ostriker & Steinhardt 1995) is based on the assumption that General Relativity governs the dynamics of astrophysical systems. This can be well approximated by Newtonian gravity in the non-relativistic regime, covering for instance planetary motions in the Solar System and galactic rotation curves (Rowland 2015; de Almeida et al 2016). Self-gravitating Newtonian disks are unstable both theoretically (Toomre 1964) and in numerical simulations (Hohl 1971) These apparently fatal problems with Newtonian gravity are generally explained by invoking massive halos of dark matter surrounding each galaxy It is hypothesised to be an undiscovered weakly interacting particle beyond the welltested standard model of particle physics (Peebles 2017a, and references therein)
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