Gravitational effects on Hong-Ou-Mandel interference in terrestrial laboratory
Abstract
In this study, we investigate the relativistic effects of Earth on Hong-Ou-Mandel (HOM) interference experiments conducted in a terrestrial laboratory. Up to the second order, we calculate the relativistic time delay from the null geodesic equation (particle perspective), and the phase shift, along with the associated effective time delay, from the Klein-Gordon equation (wave perspective). Since gravity influences both the temporal and spatial parts of the phase shift, these time delays differ and predict different coincidence probabilities. The previous HOM experiment conducted on a rotating platform shows that the wave perspective can explain the experimental results. We further explore the frame-dragging and redshift effects within an arbitrarily oriented rectangular interferometer in two distinct cases, finding that both effects can be amplified by increasing the number of light loops. Additionally, we emphasize that the next-leading order Sagnac effect, due to the gravitational acceleration, is comparable to the Thomas precession, geodetic effect, and Lense-Thirring effect. To detect the leading-order Sagnac effect and the redshift effect caused by the gravitational acceleration within the current experimental precision, we determine the number of loops photons should travel in the interferometer. Furthermore, we suggest using the difference between any two HOM patterns with different effective time delays as a probe to detect the influence of relativistic effects on quantum systems.