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Computational analysis of chemical reactions using a variational quantum eigensolver algorithm without specifying spin multiplicity

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arxiv 2303.05065 v2 pith:WKHNBDU2 submitted 2023-03-09 physics.chem-ph quant-ph

Computational analysis of chemical reactions using a variational quantum eigensolver algorithm without specifying spin multiplicity

classification physics.chem-ph quant-ph
keywords statespinquantumgroundanalysischemicalenergymultiplicity
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The analysis of a chemical reaction along the ground state potential energy surface in conjunction with an unknown spin state is challenging because electronic states must be separately computed several times using different spin multiplicities to find the lowest energy state. However, in principle, the ground state could be obtained with just a single calculation using a quantum computer without specifying the spin multiplicity in advance. In the present work, ground state potential energy curves for PtCO were calculated as a proof-of-concept using a variational quantum eigensolver (VQE) algorithm. This system exhibits a singlet-triplet crossover as a consequence of the interaction between Pt and CO. VQE calculations using a statevector simulator were found to converge to a singlet state in the bonding region, while a triplet state was obtained at the dissociation limit. Calculations performed using an actual quantum device provided potential energies within $\pm$2 kcal/mol of the simulated energies after adopting error mitigation techniques. The spin multiplicities in the bonding and dissociation regions could be clearly distinguished even in the case of a small number of shots. The results of this study suggest that quantum computing can be a powerful tool for the analysis of the chemical reactions of systems for which the spin multiplicity of the ground state and variations in this parameter are not known in advance.

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