Optimal Gaussian squeezed states for atom-interferometry in the presence of phase diffusion

Abstract

We optimize the signal-to-noise ratio of a Mach-Zehnder atom interferometer with Gaussian squeezed input states, in the presence interactions. For weak interactions, our results coincide with Phys. Rev. Lett. 100, 250406 (2008), with optimal initial number-variance σo N1/3 and optimal signal-to-noise ratio so N2/3 for total atom number N. As the interaction strength u increases past unity, phase-diffusion becomes dominant, leading to a transition in the optimal squeezing from initial number-squeezing to initial phase-squeezing with σouN and soN/u shot-noise scaling. The initial phase-squeezing translates into hold-time number-squeezing, which is less sensitive to interactions than coherent states and improves so by a factor of u.