Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Scheurer, Maximilian; Anselmetti, Gian-Luca R.; Oumarou, Oumarou; Gogolin, Christian; Rubin, Nicholas C.

doi:10.1021/acs.jctc.4c00037

J. Chem. Theory Comput.

2024

DOI: 10.1021/acs.jctc.4c00037

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Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Maximilian Scheurer,

Gian-Luca R. Anselmetti,

Oumarou Oumarou

et al.

Abstract: We propose to use wave function overlaps obtained from a quantum computer as inputs for the classical split-amplitude techniques, tailored and externally corrected coupled cluster, to achieve balanced treatment of static and dynamic correlation effects in molecular electronic structure simulations. By combining insights from statistical properties of matchgate shadows, which are used to measure quantum trial state overlaps, with classical correlation diagnostics, we can provide quantum resource estimates well … Show more

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Cited by 3 publications

References 132 publications

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Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Scheurer,

Anselmetti,

Oumarou

et al. 2024

J. Chem. Theory Comput.

Self Cite

View full text Add to dashboard Cite

We propose to use wave function overlaps obtained from a quantum computer as inputs for the classical split-amplitude techniques, tailored and externally corrected coupled cluster, to achieve balanced treatment of static and dynamic correlation effects in molecular electronic structure simulations. By combining insights from statistical properties of matchgate shadows, which are used to measure quantum trial state overlaps, with classical correlation diagnostics, we can provide quantum resource estimates well into the classically no longer exactly solvable regime. We find that rather imperfect wave functions and remarkably low shot counts are sufficient to cure qualitative failures of plain coupled cluster singles doubles and to obtain chemically precise dynamic correlation energy corrections. We provide insights into which wave function preparation schemes have a chance of yielding quantum advantage, and we test our proposed method using overlaps measured on Google’s Sycamore device.

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Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Scheurer,

Anselmetti,

Oumarou

et al. 2024

J. Chem. Theory Comput.

Self Cite

View full text Add to dashboard Cite

show abstract

Quantum Algorithms for the Variational Optimization of Correlated Electronic States with Stochastic Reconfiguration and the Linear Method

Motta,

Sung,

Shee

2024

J. Phys. Chem. A

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Solving the electronic Schrodinger equation for strongly correlated ground states is a long-standing challenge. We present quantum algorithms for the variational optimization of wave functions correlated by products of unitary operators, such as Local Unitary Cluster Jastrow (LUCJ) ansatzes, using stochastic reconfiguration (SR) and the linear method (LM). While an implementation on classical computing hardware would require exponentially growing compute cost, the cost (number of circuits and shots) of our quantum algorithms is polynomial in system size. We find that classical simulations of optimization with the linear method consistently find lower energy solutions than with the L-BFGS-B optimizer across the dissociation curves of the notoriously difficult N 2 and C 2 dimers; LUCJ predictions of the ground-state energies deviate from exact diagonalization by 1 kcal/mol or less at all points on the potential energy curve. While we do characterize the effect of shot noise on the LM optimization, these noiseless results highlight the critical but often overlooked role that optimization techniques must play in attacking the electronic structure problem (on both classical and quantum hardware), for which even mean-field optimization is formally NP hard. We also discuss the challenge of obtaining smooth curves in these strongly correlated regimes, and propose a number of quantum-friendly solutions ranging from symmetry-projected ansatz forms to a symmetry-constrained optimization algorithm.

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Evaluating a quantum-classical quantum Monte Carlo algorithm with Matchgate shadows

Huang,

Chen,

Gupt

et al. 2024

Phys. Rev. Research

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Solving the electronic structure problem of molecules and solids to high accuracy is a major challenge in quantum chemistry and condensed matter physics. The rapid emergence and development of quantum computers offer a promising route to systematically tackle this problem. Recent work by [Huggins , ] proposed a hybrid quantum-classical quantum Monte Carlo (QC-QMC) algorithm using Clifford shadows to determine the ground state of a Fermionic Hamiltonian. This approach displayed inherent noise resilience and the potential for improved accuracy compared to its purely classical counterpart. Nevertheless, the use of Clifford shadows introduces an exponentially scaling postprocessing cost. In this work, we investigate an improved QC-QMC scheme utilizing the recently developed Matchgate shadows technique [], which removes the aforementioned exponential bottleneck. We observe from experiments on quantum hardware that the use of Matchgate shadows in QC-QMC is inherently noise robust. We show that this noise resilience has a more subtle origin than in the case of Clifford shadows. Nevertheless, we find that classical postprocessing, while asymptotically efficient, requires hours of runtime on thousands of classical CPUs for even the smallest chemical systems, presenting a major challenge to the scalability of the algorithm. Published by the American Physical Society 2024

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Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Cited by 3 publications

References 132 publications

Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Tailored and Externally Corrected Coupled Cluster with Quantum Inputs

Quantum Algorithms for the Variational Optimization of Correlated Electronic States with Stochastic Reconfiguration and the Linear Method

Evaluating a quantum-classical quantum Monte Carlo algorithm with Matchgate shadows

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