Generalized hydrodynamics of integrable quantum circuits

Hübner, Friedrich; Vernier, Eric; Piroli, Lorenzo

doi:10.21468/SciPostPhys.18.4.135

SciPost Physics

Generalized hydrodynamics of integrable quantum circuits

Friedrich Hübner, Eric Vernier, Lorenzo Piroli

SciPost Phys. 18, 135 (2025) · published 24 April 2025

doi: 10.21468/SciPostPhys.18.4.135
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Abstract

Quantum circuits make it possible to simulate the continuous-time dynamics of a many-body Hamiltonian by implementing discrete Trotter steps of duration $\tau$ . However, when $\tau$ is sufficiently large, the discrete dynamics exhibit qualitative differences compared to the original evolution, potentially displaying novel features and many-body effects. We study an interesting example of this phenomenon, by considering the integrable Trotterization of a prototypical integrable model, the XXZ Heisenberg spin chain. We focus on the well-known bipartition protocol, where two halves of a large system are prepared in different macrostates and suddenly joined together, yielding non-trivial nonequilibrium dynamics. Building upon recent results and adapting the generalized hydrodynamics (GHD) of integrable models, we develop an exact large-scale description of an explicit one-dimensional quantum-circuit setting, where the input left and right qubits are initialized in two distinct product states. We explore the phenomenology predicted by the GHD equations, which depend on the Trotter step and the gate parameters. In some phases of the parameter space, we show that the quantum-circuit large-scale dynamics is qualitatively different compared to the continuous-time evolution. In particular, we find that a single microscopic defect at the junction, such as the addition of a single qubit, may change the nonequilibrium macrostate appearing at late time.

TY  - JOUR
PB  - SciPost Foundation
DO  - 10.21468/SciPostPhys.18.4.135
TI  - Generalized hydrodynamics of integrable quantum circuits
PY  - 2025/04/24
UR  - https://scipost.org/SciPostPhys.18.4.135
JF  - SciPost Physics
JA  - SciPost Phys.
VL  - 18
IS  - 4
SP  - 135
A1  - Hübner, Friedrich
AU  - Vernier, Eric
AU  - Piroli, Lorenzo
AB  - Quantum circuits make it possible to simulate the continuous-time dynamics of a many-body Hamiltonian by implementing discrete Trotter steps of duration $\tau$. However, when $\tau$ is sufficiently large, the discrete dynamics exhibit qualitative differences compared to the original evolution, potentially displaying novel features and many-body effects. We study an interesting example of this phenomenon, by considering the integrable Trotterization of a prototypical integrable model, the XXZ Heisenberg spin chain. We focus on the well-known bipartition protocol, where two halves of a large system are prepared in different macrostates and suddenly joined together, yielding non-trivial nonequilibrium dynamics. Building upon recent results and adapting the generalized hydrodynamics (GHD) of integrable models, we develop an exact large-scale description of an explicit one-dimensional quantum-circuit setting, where the input left and right qubits are initialized in two distinct product states. We explore the phenomenology predicted by the GHD equations, which depend on the Trotter step and the gate parameters. In some phases of the parameter space, we show that the quantum-circuit large-scale dynamics is qualitatively different compared to the continuous-time evolution. In particular, we find that a single microscopic defect at the junction, such as the addition of a single qubit, may change the nonequilibrium macrostate appearing at late time.
ER  -

@Article{10.21468/SciPostPhys.18.4.135,
	title={{Generalized hydrodynamics of integrable quantum circuits}},
	author={Friedrich Hübner and Eric Vernier and Lorenzo Piroli},
	journal={SciPost Phys.},
	volume={18},
	pages={135},
	year={2025},
	publisher={SciPost},
	doi={10.21468/SciPostPhys.18.4.135},
	url={https://scipost.org/10.21468/SciPostPhys.18.4.135},
}

Ontology / Topics

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Generalized hydrodynamics (GHD) Integrability/integrable models Quantum information

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¹ Friedrich Hübner,
² ³ ⁴ ⁵ Eric Vernier,
⁶ ⁷ Lorenzo Piroli

Funders for the research work leading to this publication