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Disorder-Free Localization for Benchmarking Quantum Computers

Quantum Physics 2024-10-14 v1 Quantum Gases Statistical Mechanics Strongly Correlated Electrons High Energy Physics - Lattice

Abstract

Disorder-free localization (DFL) is a phenomenon as striking as it appears to be simple: a translationally invariant state evolving under a disorder-free Hamiltonian failing to thermalize. It is predicted to occur in a number of quantum systems exhibiting emergent or native \emph{local} symmetries. These include models of lattice gauge theories and, perhaps most simply, some two-component spin chains. Though well-established analytically for special soluble examples, numerical studies of generic systems have proven difficult. Moreover, the required local symmetries are a challenge for any experimental realization. Here, we show how a canonical model of DFL can be efficiently implemented on gate-based quantum computers, which relies on our efficient encoding of three-qubit gates. We show that the simultaneous observation of the absence of correlation spreading and tunable entanglement growth to a volume law provides an ideal testbed for benchmarking the capabilities of quantum computers. In particular, the availability of a soluble limit allows for a rigorous prediction of emergent localization length scales and tunable time scales for the volume law entanglement growth, which are ideal for testing capabilities of scalable quantum computers.

Keywords

Cite

@article{arxiv.2410.08268,
  title  = {Disorder-Free Localization for Benchmarking Quantum Computers},
  author = {Jad C. Halimeh and Uliana E. Khodaeva and Dmitry L. Kovrizhin and Roderich Moessner and Johannes Knolle},
  journal= {arXiv preprint arXiv:2410.08268},
  year   = {2024}
}

Comments

$10$ pages, $3$ figures

R2 v1 2026-06-28T19:16:54.534Z