Quantum Transport Protected by Acceleration From Nonadiabaticity and Dissipation

TL;DR

This paper introduces a novel control strategy for high-fidelity, fast quantum wavepacket transport that effectively manages dissipation and non-adiabatic effects, outperforming traditional counterdiabatic methods especially at high speeds.

Contribution

The authors propose a new acceleration-based control method that optimizes quantum transport in dissipative environments, applicable to various quantum systems and surpassing existing techniques.

Findings

Maximized transport fidelity even at supersonic speeds.

Effective handling of non-Markovian bath effects.

Applicable to atoms, ions, and molecules in quantum systems.

Abstract

We put forth a hitherto unexplored control strategy that enables high-fidelity fast transport of an unstable quantum wavepacket even in the presence of bath-induced dissipation. The wavepacket, which is confined within any shallow (anharmonic) potential trap is steered in acceleration, so as to maximize the transfer fidelity. This strategy can generally optimize any non-Markovian bath-dressed continuous-variable system dynamics. It can simultaneously cope with wavepacket leakage via non-adiabatic transitions and bath-induced dissipation in an optimal fashion. It can outperform methods based on counterdiabatic fields (shortcuts to adiabaticity) particularly for fast non-adiabatic transport. Transport fidelity is maximized even for trajectories exceeding the speed of bath-excitation propagation, e.g. for supersonic transfer through phonon baths. This general approach is illustrated for optimized transfer of impurities in Bose-Einstein condensates. It is applicable to both dissipative and non-dissipative transfer of trapped atoms and ions and molecular reaction products.