Quantum effects in the Aubry transition

The Aubry transition between sliding and pinned phases, driven by the competition between two incommensurate length scales, represents a paradigm that is applicable to a large variety of microscopically distinct systems. Despite previous theoretical studies, it remains an open question to what extent quantum effects modify the transition, or are experimentally observable. An experimental platform that can potentially reach the quantum regime has recently become available at MIT in the form of trapped laser-cooled ions subject to a periodic optical potential [A. Bylinskii, D. Gangloff, I. Counts, and V. Vuletic, Observation of Aubry-type transition in finite atom chains via friction, Nat. Mater. 15, 717 (2016)]. Using path-integral Monte Carlo (PIMC) simulation methods, we analyze the impact of quantum tunneling on the sliding-to-pinned transition in this system and determine the phase diagram in terms of incommensuration and potential strength. We propose new signatures of the quantum Aubry transition that are robust against thermal and finite-size effects and that can be observed in future experiments.

Automated summary

The study investigates the quantum effects and experimental observation of the Aubry transition, analyzing the sliding-to-pinned transition in ion systems using a trapped laser-cooled ion platform. New signatures of the quantum Aubry transition are proposed, which are robust against thermal and finite-size effects and can potentially be observed in future experiments.