Abdul Kalam, Shubham Kumar, Dr. Ashok Kumar, Prof. Prasanta K. Panigrahi
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引用次数: 0
Abstract
Because of remarkable reactivity and strong electron-electron correlation effects, the precise prediction of ground state energy and chemical reactivity of hydride ion is an essential objective in quantum chemistry. Leveraging variational quantum algorithms offers a promising avenue for studying molecular properties using current noisy intermediate-scale quantum devices. This work utilises the variational approach to anticipate the ground state, reactivity, and single-electron detachment energy of the three-body hydride ion. We investigated both Hardware-Efficient Ansatz (HEA) and Chemistry-inspired ansatz based on a Unitary Coupled Cluster (UCC) on both noiseless and noisy IBM simulators. Modern error-mitigating techniques, such as Zero-Noise Extrapolation (ZNE) with unitary folding and measurement error mitigation, have been implemented to significantly reduce errors in noisy environments. This study contributes to our understanding of the quantum computational nuances of the hydride ion and addresses the question of whether quantum computers can retain the correlation energies for these correlated ions.
由于氢化物离子具有显著的反应性和强电子-电子相关效应,精确预测其基态能量和化学反应性是量子化学的一个重要目标。利用变分量子算法为使用当前噪声较大的中量级量子设备研究分子特性提供了一条前景广阔的途径。本研究利用变分法预测三体氢化物离子的基态、反应性和单电子脱离能。我们在无噪声和有噪声的 IBM 模拟器上研究了基于单元耦合簇(UCC)的硬件高效解析(HEA)和化学启发解析。现代误差缓解技术,如带有单元折叠和测量误差缓解的零噪声外推法(ZNE),已被用于显著减少噪声环境中的误差。这项研究有助于我们了解氢化物离子的量子计算细微差别,并解决了量子计算机能否保留这些相关离子的相关能的问题。
期刊介绍:
ChemistrySelect is the latest journal from ChemPubSoc Europe and Wiley-VCH. It offers researchers a quality society-owned journal in which to publish their work in all areas of chemistry. Manuscripts are evaluated by active researchers to ensure they add meaningfully to the scientific literature, and those accepted are processed quickly to ensure rapid online publication.
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