Bounds on the recurrence probability in periodically-driven quantum systems
Abstract
Periodically-driven systems are ubiquitous in science and technology. In quantum dynamics, even a small number of periodically-driven spins leads to complicated dynamics. Hence, it is of interest to understand what constraints such dynamics must satisfy. We derive a set of constraints for each number of cycles. For pure initial states, the observable being constrained is the recurrence probability. We use our constraints for detecting undesired coupling to unaccounted environments and drifts in the driving parameters. To illustrate the relevance of these results for modern quantum systems we demonstrate our findings experimentally on a trapped-ion quantum computer, and on various IBM quantum computers. Specifically, we provide two experimental examples where these constraints surpass fundamental bounds associated with known one-cycle constraints. This scheme can potentially be used to detect the effect of the environment in quantum circuits that cannot be classically simulated. Finally, we show that, in practice, testing an -cycle constraint requires executing only cycles, which makes the evaluation of constraints associated with hundreds of cycles realistic.
Cite
@article{arxiv.2105.11685,
title = {Bounds on the recurrence probability in periodically-driven quantum systems},
author = {Tanmoy Pandit and Alaina M. Green and C. Huerta Alderete and Norbert M. Linke and Raam Uzdin},
journal= {arXiv preprint arXiv:2105.11685},
year = {2022}
}
Comments
v3: The version accepted to quantum