The wave nature of a Mott insulator

TL;DR

This study reveals that a one-dimensional Mott insulator exhibits wave-like interference patterns, challenging the traditional view that such patterns only indicate superfluidity.

Contribution

It demonstrates that interference peaks can persist and even strengthen in a 1D Mott insulator, showing coherence is not exclusive to superfluid phases.

Findings

Interference peaks remain pronounced deep in the insulating regime.

Interference becomes stronger with increasing Mott fraction.

Quantum Monte Carlo simulations confirm oscillatory, exponentially decaying coherence patterns.

Abstract

Quantum phases of matter are routinely identified by coherence features, with interference patterns being one of the most directly observable quantities. In lattices, the superfluid-to-Mott-insulator (SF-MI) transition is commonly viewed as a change from wave-like coherence to particle-like localization: interference peaks are taken as a hallmark of superfluidity, whereas their disappearance is used to diagnose insulating behavior. Here, we challenge this picture for one-dimensional (1D) strongly interacting gases subject to a lattice potential. We realize a gapped Mott insulator through pinning in a shallow lattice and find that pronounced interference peaks persist deep in the insulating regime. Strikingly, the interference becomes stronger as the Mott fraction increases, demonstrating that a certain degree of coherence still exists in the insulator state. Measurements of the one-body correlation function reveal an oscillatory, exponentially decaying coherence pattern across several lattice sites, in quantitative agreement with quantum Monte Carlo (QMC) simulations. Our work shows that interference does not uniquely diagnose superfluidity and it exposes the unexpected wave nature of a 1D Mott insulator.