Quantum Circuits for Matrix-Product Unitaries
Abstract
Matrix-product unitaries (MPUs) are many-body unitary operators that, as a consequence of their tensor-network structure, preserve the entanglement area law in 1D systems. However, it is unknown how to implement an MPU as a quantum circuit since the individual tensors describing the MPU are not unitary. In this Letter, we show that a large class of MPUs can be implemented with a polynomial-depth quantum circuit. For an -site MPU built from a repeated bulk tensor with open boundary, we explicitly construct a quantum circuit of polynomial depth realizing the MPU, where the constant depends only on the bulk and boundary tensor and not the system size . We show that this class includes nontrivial unitaries that generate long-range entanglement and, in particular, contains a large class of unitaries constructed from representations of -weak Hopf algebras. Furthermore, we also adapt our construction to nonuniform translationally-varying MPUs and show that they can be implemented by a circuit of depth where , with being the bond dimension and the smallest nonzero Schmidt value of the normalized Choi state corresponding to the MPU.
Cite
@article{arxiv.2508.08160,
title = {Quantum Circuits for Matrix-Product Unitaries},
author = {Georgios Styliaris and Rahul Trivedi and J. Ignacio Cirac},
journal= {arXiv preprint arXiv:2508.08160},
year = {2026}
}
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