Determining the difference between local acceleration and local gravity: applications of the equivalence principle to relativistic trajectories
American Journal of Physics American Association of Physics Teachers 92:6 (2024) 444-449
Abstract:
We show by direct calculation that the common equivalence principle explanation for why gravity must deflect light is quantitatively incorrect by a factor of three in Schwarzschild geometry. It is, therefore, possible, at least as a matter of principle, to tell the difference between local acceleration and a true gravitational field by measuring the local deflection of light. We calculate as well the deflection of test particles of arbitrary energy and construct a leading-order coordinate transformation from Schwarzschild to local inertial coordinates, which shows explicitly how the effects of spatial curvature manifest locally for relativistic trajectories of both finite and vanishing rest mass particles.The dynamics of accretion flows near to the innermost stable circular orbit
Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 529:2 (2024) 1900-1916
Testing theories of accretion and gravity with super-extremal Kerr discs
Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 527:3 (2023) 5956-5973
Fundamental scaling relationships revealed in the optical light curves of tidal disruption events
Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 527:2 (2023) 2452-2489
Complete characterization of the orbital shapes of the noncircular Kerr geodesic solutions with circular orbit constants of motion
Physical Review D American Physical Society (APS) 107:12 (2023) 124058