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Main Authors: Granet, Etienne, Kikuchi, Yuta, Dreyer, Henrik, Rinaldi, Enrico
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.07530
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author Granet, Etienne
Kikuchi, Yuta
Dreyer, Henrik
Rinaldi, Enrico
author_facet Granet, Etienne
Kikuchi, Yuta
Dreyer, Henrik
Rinaldi, Enrico
contents The Sachdev-Ye-Kitaev (SYK) model describes a strongly correlated quantum system that shows a strong signature of quantum chaos. Due to its chaotic nature, the simulation of real-time dynamics becomes quickly intractable by means of classical numerics, and thus, quantum simulation is deemed to be an attractive alternative. Nevertheless, quantum simulations of the SYK model on noisy quantum processors are severely limited by the complexity of its Hamiltonian. In this work, we simulate the real-time dynamics of a sparsified version of the SYK model with 24 Majorana fermions on a trapped-ion quantum processor. We adopt a randomized quantum algorithm, TETRIS, and develop an error mitigation technique tailored to the algorithm. Leveraging the hardware's high-fidelity quantum operations and all-to-all connectivity of the qubits, we successfully calculate the Loschmidt amplitude for sufficiently long times so that its decay is observed. Based on the experimental and further numerical results, we assess the future possibility of larger-scale simulations of the SYK model by estimating the required quantum resources. Moreover, we present a scalable mirror-circuit benchmark based on the randomized SYK Hamiltonian and the TETRIS algorithm, which we argue provides a better estimate of the decay of fidelity for local observables than standard mirror-circuits.
format Preprint
id arxiv_https___arxiv_org_abs_2507_07530
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Simulating sparse SYK model with a randomized algorithm on a trapped-ion quantum computer
Granet, Etienne
Kikuchi, Yuta
Dreyer, Henrik
Rinaldi, Enrico
Quantum Physics
The Sachdev-Ye-Kitaev (SYK) model describes a strongly correlated quantum system that shows a strong signature of quantum chaos. Due to its chaotic nature, the simulation of real-time dynamics becomes quickly intractable by means of classical numerics, and thus, quantum simulation is deemed to be an attractive alternative. Nevertheless, quantum simulations of the SYK model on noisy quantum processors are severely limited by the complexity of its Hamiltonian. In this work, we simulate the real-time dynamics of a sparsified version of the SYK model with 24 Majorana fermions on a trapped-ion quantum processor. We adopt a randomized quantum algorithm, TETRIS, and develop an error mitigation technique tailored to the algorithm. Leveraging the hardware's high-fidelity quantum operations and all-to-all connectivity of the qubits, we successfully calculate the Loschmidt amplitude for sufficiently long times so that its decay is observed. Based on the experimental and further numerical results, we assess the future possibility of larger-scale simulations of the SYK model by estimating the required quantum resources. Moreover, we present a scalable mirror-circuit benchmark based on the randomized SYK Hamiltonian and the TETRIS algorithm, which we argue provides a better estimate of the decay of fidelity for local observables than standard mirror-circuits.
title Simulating sparse SYK model with a randomized algorithm on a trapped-ion quantum computer
topic Quantum Physics
url https://arxiv.org/abs/2507.07530