Local random quantum circuits form approximate designs on arbitrary architectures
Abstract
We consider random quantum circuits (RQC) on arbitrary connected graphs whose edges determine the allowed -qudit interactions. Prior work has established that such -qudit circuits with local dimension on 1D, complete, and -dimensional graphs form approximate unitary designs, that is, they generate unitaries from distributions close to the Haar measure on the unitary group after polynomially many gates. Here, we extend those results by proving that RQCs comprised of gates on a wide class of graphs form approximate unitary -designs. We prove that RQCs on graphs with spanning trees of bounded degree and height form -designs after gates, where is the number of edges in the graph. Furthermore, we identify larger classes of graphs for which RQCs generate approximate designs in polynomial circuit size. For , we show that RQCs on graphs of certain maximum degrees form designs after gates, providing explicit constants. We determine our circuit size bounds from the spectral gaps of local Hamiltonians. To that end, we extend the finite-size (or Knabe) method for bounding gaps of frustration-free Hamiltonians on regular graphs to arbitrary connected graphs. We further introduce a new method based on the Detectability Lemma for determining the spectral gaps of Hamiltonians on arbitrary graphs. Our methods have wider applicability as the first method provides a succinct alternative proof of [Commun. Math. Phys. 291, 257 (2009)] and the second method proves that RQCs on any connected architecture form approximate designs in quasi-polynomial circuit size.
Cite
@article{arxiv.2310.19355,
title = {Local random quantum circuits form approximate designs on arbitrary architectures},
author = {Shivan Mittal and Nicholas Hunter-Jones},
journal= {arXiv preprint arXiv:2310.19355},
year = {2023}
}