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Bibliographic Details
Main Authors: Ding, Qi-Ming, Peng, Jiawei, Huang, Junxiang, Zhang, Yukun, Wang, Huiyuan, Xu, Xiaosi, Ren, Jiajun, Ma, Yingjin, Yuan, Xiao
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.21255
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author Ding, Qi-Ming
Peng, Jiawei
Huang, Junxiang
Zhang, Yukun
Wang, Huiyuan
Xu, Xiaosi
Ren, Jiajun
Ma, Yingjin
Yuan, Xiao
author_facet Ding, Qi-Ming
Peng, Jiawei
Huang, Junxiang
Zhang, Yukun
Wang, Huiyuan
Xu, Xiaosi
Ren, Jiajun
Ma, Yingjin
Yuan, Xiao
contents Accurate ground-state calculations on noisy quantum computers are fundamentally limited by restricted ansatz expressivity and unavoidable hardware errors. We introduce a hybrid-quantum classical framework that simultaneously addresses these challenges. Our method systematically purifies noisy two electron reduced density matrices from quantum devices by enforcing N-representability conditions through efficient semidefinite programming, guided by a norm-based distance constraint to the experimental data. To implement this constraint, we develop a hardware efficient calibration protocol based on Clifford circuits. We demonstrate near full configuration interaction accuracy for ground-state energies of H2, LiH, and H4, and compute precise scattering intensities for C6H8 on noisy hardware. This approach surpasses conventional methods by simultaneously overcoming both ansatz limitations and hardware noise, establishing a scalable route to quantum advantage and marking a critical step toward reliable simulations of complex molecularnsystems on noisy devices.
format Preprint
id arxiv_https___arxiv_org_abs_2510_21255
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Obtaining Accurate Ground-State Properties on Near-term Quantum Devices
Ding, Qi-Ming
Peng, Jiawei
Huang, Junxiang
Zhang, Yukun
Wang, Huiyuan
Xu, Xiaosi
Ren, Jiajun
Ma, Yingjin
Yuan, Xiao
Quantum Physics
Accurate ground-state calculations on noisy quantum computers are fundamentally limited by restricted ansatz expressivity and unavoidable hardware errors. We introduce a hybrid-quantum classical framework that simultaneously addresses these challenges. Our method systematically purifies noisy two electron reduced density matrices from quantum devices by enforcing N-representability conditions through efficient semidefinite programming, guided by a norm-based distance constraint to the experimental data. To implement this constraint, we develop a hardware efficient calibration protocol based on Clifford circuits. We demonstrate near full configuration interaction accuracy for ground-state energies of H2, LiH, and H4, and compute precise scattering intensities for C6H8 on noisy hardware. This approach surpasses conventional methods by simultaneously overcoming both ansatz limitations and hardware noise, establishing a scalable route to quantum advantage and marking a critical step toward reliable simulations of complex molecularnsystems on noisy devices.
title Obtaining Accurate Ground-State Properties on Near-term Quantum Devices
topic Quantum Physics
url https://arxiv.org/abs/2510.21255