Related papers: Computational power of one- and two-dimensional dual-unitary quantum circuits

Computational power of one- and two-dimensional dual-unitary quantum circuits

URL: http://arxiv.org/abs/2103.09211v2
Date: Tue, 18 Jan 2022 16:36:20 GMT
Title: Computational power of one- and two-dimensional dual-unitary quantum circuits
Authors: Ryotaro Suzuki, Kosuke Mitarai, Keisuke Fujii
Abstract summary: Quantum circuits that are classically simulatable tell us when quantum computation becomes less powerful than or equivalent to classical computation. We make use of dual-unitary quantum circuits (DUQCs), which have been recently investigated as exactly solvable models of non-equilibrium physics.
Score: 0.6946929968559495
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Quantum circuits that are classically simulatable tell us when quantum computation becomes less powerful than or equivalent to classical computation. Such classically simulatable circuits are of importance because they illustrate what makes universal quantum computation different from classical computers. In this work, we propose a novel family of classically simulatable circuits by making use of dual-unitary quantum circuits (DUQCs), which have been recently investigated as exactly solvable models of non-equilibrium physics, and we characterize their computational power. Specifically, we investigate the computational complexity of the problem of calculating local expectation values and the sampling problem of one-dimensional DUQCs, and we generalize them to two spatial dimensions. We reveal that a local expectation value of a DUQC is classically simulatable at an early time, which is linear in a system length. In contrast, in a late time, they can perform universal quantum computation, and the problem becomes a BQP-complete problem. Moreover, classical simulation of sampling from a DUQC turns out to be hard.

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