使用量子计算算法描述CO2–NH3相互作用的反应和振动能量学

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY
Manh Tien Nguyen, Yueh-Lin Lee, D. Alfonso, Qing Shao, Yuhua Duan
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引用次数: 0

摘要

二氧化碳捕获是解决全球变暖问题的关键。胺基溶剂被广泛用于化学吸收二氧化碳。因此,研究胺基溶剂对CO2的化学吸收对于更好地理解和优化CO2捕获过程至关重要。在这里,我们使用量子计算算法来量化CO2与简化胺基溶剂模型- nh3之间的分子振动能和反应途径。分子的振动性质对理解反应动力学是很重要的。然而,分子大小与振动性质的非调和效应的强度相关,这可能是使用经典计算来解决的挑战。量子计算可以通过包含非调和性来帮助增强分子振动计算。我们在量子模拟器中实现了一种变分量子特征求解(VQE)算法来计算CO2和NH3反应的反应物和生成物的基态振动能量。VQE计算得到CO2和NH3的地面振动能,其精度与经典计算相似。在存在硬件噪声的情况下,电路深度较浅的化学紧凑型启发式(Compact Heuristic for Chemistry, CHC)簇的性能优于单一振动耦合簇。“零噪声外推”误差缓解方法与CHC分析相结合,提高了振动计算精度。用量子运动方程方法得到了CO2和NH3的激发态。采用量子Hartree-Fock (HF)嵌入算法计算电子能,相应的反应谱优于偶联簇单和双反应谱,而比偶联簇双反应谱更准确。我们的研究展示了量子计算在二氧化碳捕获反应研究中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Description of reaction and vibrational energetics of CO2–NH3 interaction using quantum computing algorithms
CO2 capture is critical to solving global warming. Amine-based solvents are extensively used to chemically absorb CO2. Thus, it is crucial to study the chemical absorption of CO2 by amine-based solvents to better understand and optimize CO2 capture processes. Here, we use quantum computing algorithms to quantify molecular vibrational energies and reaction pathways between CO2 and a simplified amine-based solvent model—NH3. Molecular vibrational properties are important to understanding kinetics of reactions. However, the molecule size correlates with the strength of anharmonicity effect on vibrational properties, which can be challenging to address using classical computing. Quantum computing can help enhance molecular vibrational calculations by including anharmonicity. We implement a variational quantum eigensolver (VQE) algorithm in a quantum simulator to calculate ground state vibrational energies of reactants and products of the CO2 and NH3 reaction. The VQE calculations yield ground vibrational energies of CO2 and NH3 with similar accuracy to classical computing. In the presence of hardware noise, Compact Heuristic for Chemistry (CHC) ansatz with shallower circuit depth performs better than Unitary Vibrational Coupled Cluster. The “Zero Noise Extrapolation” error-mitigation approach in combination with CHC ansatz improves the vibrational calculation accuracy. Excited vibrational states are accessed with quantum equation of motion method for CO2 and NH3. Using quantum Hartree–Fock (HF) embedding algorithm to calculate electronic energies, the corresponding reaction profile compares favorably with Coupled Cluster Singles and Doubles while being more accurate than HF. Our research showcases quantum computing applications in the study of CO2 capture reactions.
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CiteScore
9.90
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