A Multi-path Interferometer with Ultracold Atoms Trapped in an Optical Lattice

Abstract

We study an ultra-cold gas of N bosons trapped in a one dimensional M-site optical lattice perturbed by a spatially dependent potential g· xj, where the unknown coupling strength g is to be estimated. We find that the measurement uncertainty is bounded by g1N (Mj-1). For a typical case of a linear potential, the sensitivity improves as M-1, which is a result of multiple interferences between the sites -- an advantage of multi-path interferometers over the two-mode setups. Next, we calculate the estimation sensitivity for a specific measurement where, after the action of the potential, the particles are released from the lattice and form an interference pattern. If the parameter is estimated by a least-square fit of the average density to the interference pattern, the sensitivity still scales like M-1 for linear potentials and can be further improved by preparing a properly correlated initial state in the lattice.