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Hauptverfasser: Cao, Yingkang, Liu, Suying, Deng, Haowei, Xia, Zihan, Wu, Xiaodi, Wang, Yu-Xin
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2412.07764
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author Cao, Yingkang
Liu, Suying
Deng, Haowei
Xia, Zihan
Wu, Xiaodi
Wang, Yu-Xin
author_facet Cao, Yingkang
Liu, Suying
Deng, Haowei
Xia, Zihan
Wu, Xiaodi
Wang, Yu-Xin
contents Achieving noise resilience is an outstanding challenge in Hamiltonian-based quantum computation. To this end, energy-gap protection provides a promising approach, where the desired quantum dynamics are encoded into the ground space of a penalty Hamiltonian that suppresses unwanted noise processes. However, existing approaches either explicitly require high-weight penalty terms that are not directly accessible in current hardware, or utilize non-commuting $2$-local Hamiltonians, which typically leads to an exponentially small energy gap. In this work, we provide a general recipe for designing error-resilient Hamiltonian simulations, making use of an excited encoding subspace stabilized by solely $2$-local commuting Hamiltonians. Our results thus overcome a no-go theorem previously derived for ground-space encoding that prevents noise suppression schemes with such Hamiltonians. Importantly, our method is scalable as it only requires penalty terms that scale polynomially with system size. To illustrate the utility of our approach, we further apply this method to a variety of $1$- and $2$-dimensional many-body spin models, potentially extending the duration of high-fidelity simulation by orders of magnitude in current hardware.
format Preprint
id arxiv_https___arxiv_org_abs_2412_07764
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Robust analog quantum simulators by quantum error-detecting codes
Cao, Yingkang
Liu, Suying
Deng, Haowei
Xia, Zihan
Wu, Xiaodi
Wang, Yu-Xin
Quantum Physics
Achieving noise resilience is an outstanding challenge in Hamiltonian-based quantum computation. To this end, energy-gap protection provides a promising approach, where the desired quantum dynamics are encoded into the ground space of a penalty Hamiltonian that suppresses unwanted noise processes. However, existing approaches either explicitly require high-weight penalty terms that are not directly accessible in current hardware, or utilize non-commuting $2$-local Hamiltonians, which typically leads to an exponentially small energy gap. In this work, we provide a general recipe for designing error-resilient Hamiltonian simulations, making use of an excited encoding subspace stabilized by solely $2$-local commuting Hamiltonians. Our results thus overcome a no-go theorem previously derived for ground-space encoding that prevents noise suppression schemes with such Hamiltonians. Importantly, our method is scalable as it only requires penalty terms that scale polynomially with system size. To illustrate the utility of our approach, we further apply this method to a variety of $1$- and $2$-dimensional many-body spin models, potentially extending the duration of high-fidelity simulation by orders of magnitude in current hardware.
title Robust analog quantum simulators by quantum error-detecting codes
topic Quantum Physics
url https://arxiv.org/abs/2412.07764