Breakdown of the Newton-Einstein Standard Gravity at Low Acceleration in Internal Dynamics of Wide Binary Stars

Abstract

A gravitational anomaly is found at weak gravitational acceleration gN < 10-9 m s-2 from analyses of the dynamics of wide binary stars selected from the Gaia DR3 database that have accurate distances, proper motions, and reliably inferred stellar masses. Implicit high-order multiplicities are required and the multiplicity fraction is calibrated so that binary internal motions agree statistically with Newtonian dynamics at a high enough acceleration of 10-8 m s-2. The observed sky-projected motions and separation are deprojected to the three-dimensional relative velocity v and separation r through a Monte Carlo method, and a statistical relation between the Newtonian acceleration gN GM/r2 (where M is the total mass of the binary system) and a kinematic acceleration g v2/r is compared with the corresponding relation predicted by Newtonian dynamics. The empirical acceleration relation at < 10-9 m s-2 systematically deviates from the Newtonian expectation. A gravitational anomaly parameter δobs-newt between the observed acceleration at gN and the Newtonian prediction is measured to be: δobs-newt= 0.034 0.007 and 0.109 0.013 at gN≈10-8.91 and 10-10.15 m s-2, from the main sample of 26,615 wide binaries within 200 pc. These two deviations in the same direction represent a 10σ significance. The deviation represents a direct evidence for the breakdown of standard gravity at weak acceleration. At gN=10-10.15 m s-2, the observed to Newton predicted acceleration ratio is gobs/gpred=102δobs-newt=1.43 0.06. This systematic deviation agrees with the boost factor that the AQUAL theory predicts for kinematic accelerations in circular orbits under the Galactic external field.