English

A sharp phase transition in linear cross-entropy benchmarking

Quantum Physics 2023-05-10 v1 Statistical Mechanics

Abstract

Demonstrations of quantum computational advantage and benchmarks of quantum processors via quantum random circuit sampling are based on evaluating the linear cross-entropy benchmark (XEB). A key question in the theory of XEB is whether it approximates the fidelity of the quantum state preparation. Previous works have shown that the XEB generically approximates the fidelity in a regime where the noise rate per qudit ε\varepsilon satisfies εN1\varepsilon N \ll 1 for a system of NN qudits and that this approximation breaks down at large noise rates. Here, we show that the breakdown of XEB as a fidelity proxy occurs as a sharp phase transition at a critical value of εN\varepsilon N that depends on the circuit architecture and properties of the two-qubit gates, including in particular their entangling power. We study the phase transition using a mapping of average two-copy quantities to statistical mechanics models in random quantum circuit architectures with full or one-dimensional connectivity. We explain the phase transition behavior in terms of spectral properties of the transfer matrix of the statistical mechanics model and identify two-qubit gate sets that exhibit the largest noise robustness.

Keywords

Cite

@article{arxiv.2305.04954,
  title  = {A sharp phase transition in linear cross-entropy benchmarking},
  author = {Brayden Ware and Abhinav Deshpande and Dominik Hangleiter and Pradeep Niroula and Bill Fefferman and Alexey V. Gorshkov and Michael J. Gullans},
  journal= {arXiv preprint arXiv:2305.04954},
  year   = {2023}
}

Comments

17 pages, 8 figures

R2 v1 2026-06-28T10:29:04.222Z