Collapse and revival dynamics of superfluids of ultracold atoms in optical lattices

TL;DR

This paper investigates the collapse and revival phenomena of ultracold atoms in optical lattices, revealing how initial state squeezing and multi-band interactions influence the observed interference patterns.

Contribution

It introduces a mean-field model incorporating two- and three-body interactions to explain complex collapse-revival dynamics and links initial state squeezing to interference visibility.

Findings

Number squeezing affects revival visibility

Multi-band virtual transitions generate complex frequencies

Model fits experimental data to reveal interaction effects

Abstract

Recent experiments have shown a remarkable number of collapse-and-revival oscillations of the matter-wave coherence of ultracold atoms in optical lattices [Will et al., Nature 465, 197 (2010)]. Using a mean-field approximation to the Bose-Hubbard model, we show that the visibility of collapse-and-revival interference patterns reveal number squeezing of the initial superfluid state. To describe the dynamics, we use an effective Hamiltonian that incorporates the intrinsic two-body and induced three-body interactions, and we analyze in detail the resulting complex pattern of collapse-and-revival frequencies generated by virtual transitions to higher bands, as a function of lattice parameters and mean-atom number. Our work shows that a combined analysis of both the multiband, non-stationary dynamics in the final deep lattice, and the number-squeezing of the initial superfluid state, explains important characteristics of optical lattice collapse-and-revival physics. Finally, by treating the two- and three-body interaction strengths, and the coefficients describing the initial superposition of number states, as free parameters in a fit to the experimental data it should be possible to go beyond some of the limitations of our model and obtain insight into the breakdown of the mean-field theory for the initial state or the role of nonperturbative effects in the final state dynamics.