Low-Acceleration Gravitational Anomaly from Bayesian 3D Modeling of Wide Binary Orbits: Methodology and Results with Gaia Data Release 3
Abstract
Isolated wide binary stars provide natural laboratories to directly probe gravity for Newtonian acceleration gN 10-9 m s-2. Recent statistical analyses of wide binaries have been performed only with sky-projected relative velocities vp in the pairs. A new method of Bayesian orbit modeling exploiting three relative velocity components including the radial component vr is developed to measure the gravitational anomaly parameter 10γg10Geff/GN where Geff is the effective gravitational constant for pseudo-Newtonian elliptical orbits, while GN is Newton's constant. The method infers individual probability distributions of and then combines the independent distributions to obtain a consolidated distribution in a specific range of gN. Here the method is described and applied to a sample of 312 wide binaries in a broad dynamic range 10-11.0 gN 10-6.7 m s-2 with vr uncertainties in the range 168<σvr<380 m s-1 selected from the Gaia DR3 database. The following results are obtained: = 0.000 0.011 (Nbinary=125) for the high-acceleration regime (10-7.9 gN 10-6.7 m s-2) agreeing well with Newton, but = 0.085 0.040 or γg=1.48-0.23+0.33 (35) for a MOND regime (10-11.0 gN 10-9.5 m s-2) and = 0.063 0.015 or γg=1.34-0.08+0.10 (111) for a MOND+transition regime (10-11.0 gN 10-8.5 m s-2). These results show that a gravitational anomaly is evident for gN 10-9 m s-2 and in the MOND regime ( 10-9.5 m s-2) agrees with the prediction (≈ 0.07) of MOND gravity theories.
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