Enhancing quantum computations with the synergy of auxiliary field quantum Monte Carlo and computational basis tomography

• URL: http://arxiv.org/abs/2502.20066v1
• Date: Thu, 27 Feb 2025 13:16:16 GMT
• Title: Enhancing quantum computations with the synergy of auxiliary field quantum Monte Carlo and computational basis tomography
• Authors: Viktor Khinevich, Wataru Mizukami,
• Abstract summary: auxiliary-field quantum Monte Carlo (QC-AFQMC) algorithm proposed by Huggins et al.<n>We demonstrate the effectiveness of QC-CBT-AFQMC on molecular systems such as the hydroxyl radical, ethylene, and the nitrogen molecule.<n>Results highlight the potential of QC-CBT-AFQMC as a practical method for quantum computational chemistry.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: In general, quantum chemical calculations using quantum computers do not accurately describe dynamical correlation effects. The quantum-classical auxiliary-field quantum Monte Carlo (QC-AFQMC) algorithm proposed by Huggins et al. [Nature 603, 416-420 (2022)] addresses this challenge effectively. However, approaches such as classical and matchgate shadow tomography often require deeper circuits or large numbers of shots, making them less practical on current quantum hardware. In contrast, computational basis tomography (CBT) employs shallow circuits and is thus more suited to realistically constrained shot budgets, enabling efficient extraction of CI coefficients even with near-term quantum devices. We demonstrate the effectiveness of QC-CBT-AFQMC on molecular systems such as the hydroxyl radical, ethylene, and the nitrogen molecule. The resulting potential energy curves agree closely with established classical benchmarks, including CCSD(T) and NEVPT2. We also examine the influence of CBT measurement counts on accuracy, showing that subtracting the active-space AFQMC energy mitigates measurement-induced errors. Furthermore, we apply QC-CBT-AFQMC to estimate reaction barriers in [3+2]-cycloaddition reactions, achieving agreement with high-level references and successfully incorporating complete basis set extrapolation techniques. These results highlight the potential of QC-CBT-AFQMC as a practical method for quantum computational chemistry.

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