English

Practical learning of multi-time statistics in open quantum systems

Quantum Physics 2026-02-05 v2

Abstract

Randomised measurements can efficiently characterise many-body quantum states by learning the expectation values of observables with low Pauli weights. In this paper, we generalise the theoretical tools of classical shadow tomography to the temporal domain to explore multi-time phenomena. This enables us to efficiently learn the features of multi-time processes such as correlated error rates, multi-time non-Markovianity, and temporal entanglement. We test the efficacy of these tools on a noisy quantum processor to characterise its noise features. Implementing these tools requires mid-circuit instruments, typically slow or unavailable in current quantum hardware. We devise a protocol to achieve fast and reliable instruments such that these multi-time distributions can be learned to a high accuracy. This enables a compact matrix product operator representation of large processes allowing us to showcase a reconstructed 20-step process (whose naive dimensionality is that of a 42-qubit state). Our techniques are pertinent to generic quantum stochastic dynamical processes, with a scope ranging across condensed matter physics, quantum biology, and in-depth diagnostics of noisy intermediate-scale quantum devices.

Keywords

Cite

@article{arxiv.2412.17862,
  title  = {Practical learning of multi-time statistics in open quantum systems},
  author = {Gregory A. L. White and Lloyd C. L. Hollenberg and Charles D. Hill and Kavan Modi},
  journal= {arXiv preprint arXiv:2412.17862},
  year   = {2026}
}

Comments

26 pages, 7 figures; split off and expanded from earlier version of arXiv:2107.13934

R2 v1 2026-06-28T20:47:15.591Z