The fundamental theories of general relativity and quantum mechanics are incompatible, presenting a significant theoretical challenge. General relativity offers an effective description of gravity and large-scale dynamics, while quantum mechanics describes phenomena for atomic- to Planck-scale. The Wigner rotation angle (WRA) of a photon induced by gravity, where relativistic effects become observable in its quantum spin state, is a significant point of interest as a promising candidate for direct observation near Earth by considering its small but measurable order. In this paper, we reveal that the momentum-dependent WRA displays a non-reciprocal characteristic. This distinct behavior leads to a measurable relative WRA difference between two paths of an interferometer within the Earth's gravitational field, while the WRA of a photon has conventionally been viewed as having a trivial value on a closed loop. Building on this finding, we propose an experiment that can be used to test the theoretical framework of the WRA induced in curved spacetime through the use of the Hong-Ou-Mandel (HOM) quantum interference effect for photons in near-Earth orbits. We show that in our proposed experiment the coincident photon counting rate depends on the difference of the momentum-dependent WRA in the two arms of an interferometer.
Comment: 21 pages, 3 figures for main text