Properties of Fractionally Quantized Recurrence Times for Interacting Spin Models

Quancheng Liu, David A. Kessler, Eli Barkai

Research output: Working paper / PreprintPreprint

3 Downloads (Pure)

Abstract

Recurrence time quantifies the duration required for a physical system to return to its initial state, playing a pivotal role in understanding the predictability of complex systems. In quantum systems with subspace measurements, recurrence times are governed by Anandan-Aharonov phases, yielding fractionally quantized recurrence times. However, the fractional quantization phenomenon in interacting quantum systems remains poorly explored. Here, we address this gap by establishing universal lower and upper bounds for recurrence times in interacting spins. Notably, we investigate scenarios where these bounds are approached, shedding light on the speed of quantum processes under monitoring. In specific cases, our findings reveal that the complex many-body system can be effectively mapped onto a dynamical system with a single quasi-particle, leading to the discovery of integer quantized recurrence times. Our research yields a valuable link between recurrence times and the number of dark states in the system, thus providing a deeper understanding of the intricate interplay between quantum recurrence, measurements, and interaction effects.
Original languageEnglish
PublisherarXiv preprint
DOIs
StatePublished - 18 Jan 2024

Bibliographical note

5+5 pages, 3+3 figures

Keywords

  • cond-mat.stat-mech
  • quant-ph

Fingerprint

Dive into the research topics of 'Properties of Fractionally Quantized Recurrence Times for Interacting Spin Models'. Together they form a unique fingerprint.

Cite this