Nonasymptotic bounds for quantum purity amplification
Abstract
In quantum purity amplification, one is given copies of a noisy quantum state and asked to prepare copies of its principal eigenstate . Several prior works have derived information-theoretically optimal algorithms for this problem, but the bounds they prove are only shown in the asymptotic regime as the number of samples tends to infinity. In this paper, we establish the following nonasymptotic guarantee: if 's eigenvalues are sorted and , then \begin{equation*} n = O\Big(k + \frac{k}{\delta} \cdot \frac{1-p_d}{(p_d-p_{d-1})^2}\Big) \end{equation*} copies suffice to output a state with fidelity at least with . Our bound holds for arbitrary spectra, and is independent of the dimension . In the case of depolarizing noise, our finite-sample guarantee matches the optimal asymptotic scaling. Our proof is based on the combinatorics of random Young diagrams.
Cite
@article{arxiv.2605.27262,
title = {Nonasymptotic bounds for quantum purity amplification},
author = {Thilo Scharnhorst and Jack Spilecki and John Wright},
journal= {arXiv preprint arXiv:2605.27262},
year = {2026}
}