Relative Acceleration Noise Mitigation for Entangling Masses via Quantum Gravity.

Relative accelerations between a mass undergoing matter-wave interference and the associated apparatus, when not tracked, can appear as dephasing. It can be an important limiting factor in interferometry with large masses. Here we advocate taking conceptually the simplest solution: putting both the interfering mass and its associated apparatus in a freely falling capsule, so that the strongest inertial noise components vanish due to the equivalence principle. In this setting, we investigate two of the most important remaining noise sources: (a) the non-inertial jitter of the experimental setup which arises through gas collisions and photon scattering on the experimental apparatus as well as the walls of the enclosing capsule, and (b) the gravity-gradient noise, namely the fluctuating curvature change in a finite sized capsule arising from any untracked motion of external masses. We show that the former can be reduced below desired values by appropriate pressures and temperatures, while the latter can be fully mitigated in a controlled environment. We finally apply the analysis to a recent proposal for testing the quantum nature of gravity [S. Bose et. al. Phys. Rev. Lett 119, 240401 (2017)] through the entanglement of two masses undergoing interferometry. We show that the relevant entanglement witnessing is feasible in a freely falling capsule with achievable levels of relative acceleration noise.