Energy nonconservation and relativistic trajectories: Unimodular gravity and beyond
Yuri Bonder, Jónatan Herrera, A. M. Rubiol
Abstract
Energy conservation has the status of a fundamental physical principle. However, measurements in quantum mechanics do not comply with energy conservation. Therefore, it is expected that a more fundamental theory of gravity---one that is less incompatible with quantum mechanics---should admit energy nonconservations. This paper begins by identifying the conditions for a theory to have an energy-momentum tensor that is not conserved. Then, the trajectory equation for pointlike particles that lose energy is derived, showing that energy nonconservation produces a particular acceleration. As an example, the unimodular theory of gravity is studied. Interestingly, in spherical symmetry, given that there is a generalized Birkhoff theorem and that the energy-momentum tensor divergence is a closed form, the trajectories of test particles that lose energy can be found using well-known methods. Finally, limits on the energy nonconservation parameters are set using Solar System observations.