Quantum limited measurement of space-time curvature with scaling beyond the conventional Heisenberg limit
arXiv:1702.02697 · doi:10.1103/PhysRevA.96.041801
Abstract
We study the problem of estimating the phase shift due to the general relativistic time dilation in the interference of photons using a non-linear Mach-Zender interferometer setup. By introducing two non-linear Kerr materials, one in the bottom and one in the top arm, we can measure the non-linear phase $Ï_{NL}$ produced by the space-time curvature and achieve a scaling of the standard deviation with photon number ($N$) of $1/N^β$ where $β> 1$, which exceeds the conventional Heisenberg limit of a linear interferometer ($1/N$). The non-linear phase shift is an effect that is amplified by the intensity of the probe field. In a regime of high number of photons, this effect can dominate over the linear phase shift.
8 pages, 4 figures, Closest to published version