Classical and quantum cost of measurement strategies for quantum-enhanced auxiliary field quantum Monte Carlo

Kiser, Matthew; Schroeder, Anna; Anselmetti, Gian-Luca R; Kumar, Chandan; Moll, Nikolaj; Streif, Michael; Vodola, Davide

doi:10.1088/1367-2630/ad2f67

New J. Phys.

2024

DOI: 10.1088/1367-2630/ad2f67

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Classical and quantum cost of measurement strategies for quantum-enhanced auxiliary field quantum Monte Carlo

Matthew Kiser,

Anna Schroeder,

Gian-Luca R Anselmetti

et al.

Abstract: Quantum-enhanced auxiliary field quantum Monte Carlo (QC-AFQMC) uses output from a quantum computer to increase the accuracy of its classical counterpart. The algorithm requires the estimation of overlaps between walker states and a trial wavefunction prepared on the quantum computer. We study the applicability of this algorithm in terms of the number of measurements required from the quantum computer and the classical costs of post-processing those measurements. We compare the classical post-processing costs … Show more

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Cited by 3 publications

References 66 publications

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Modeling Heterogeneous Catalysis Using Quantum Computers: An Academic and Industry Perspective

Hariharan,

Kinge,

Visscher

2024

J. Chem. Inf. Model.

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Heterogeneous catalysis plays a critical role in many industrial processes, including the production of fuels, chemicals, and pharmaceuticals, and research to improve current catalytic processes is important to make the chemical industry more sustainable. Despite its importance, the challenge of identifying optimal catalysts with the required activity and selectivity persists, demanding a detailed understanding of the complex interactions between catalysts and reactants at various length and time scales. Density functional theory (DFT) has been the workhorse in modeling heterogeneous catalysis for more than three decades. While DFT has been instrumental, this review explores the application of quantum computing algorithms in modeling heterogeneous catalysis, which could bring a paradigm shift in our approach to understanding catalytic interfaces. Bridging academic and industrial perspectives by focusing on emerging materials, such as multicomponent alloys, single-atom catalysts, and magnetic catalysts, we delve into the limitations of DFT in capturing strong correlation effects and spin-related phenomena. The review also presents important algorithms and their applications relevant to heterogeneous catalysis modeling to showcase advancements in the field. Additionally, the review explores embedding strategies where quantum computing algorithms handle strongly correlated regions, while traditional quantum chemistry algorithms address the remainder, thereby offering a promising approach for large-scale heterogeneous catalysis modeling. Looking forward, ongoing investments by academia and industry reflect a growing enthusiasm for quantum computing's potential in heterogeneous catalysis research. The review concludes by envisioning a future where quantum computing algorithms seamlessly integrate into research workflows, propelling us into a new era of computational chemistry and thereby reshaping the landscape of modeling heterogeneous catalysis.

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Modeling Heterogeneous Catalysis Using Quantum Computers: An Academic and Industry Perspective

Hariharan,

Kinge,

Visscher

2024

J. Chem. Inf. Model.

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Improved modularity and new features in `ipie`: Toward even larger AFQMC calculations on CPUs and GPUs at zero and finite temperatures

Jiang,

Baumgarten,

Loos

et al. 2024

The Journal of Chemical Physics

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ipie is a Python-based auxiliary-field quantum Monte Carlo (AFQMC) package that has undergone substantial improvements since its initial release [Malone et al., J. Chem. Theory Comput. 19(1), 109–121 (2023)]. This paper outlines the improved modularity and new capabilities implemented in ipie. We highlight the ease of incorporating different trial and walker types and the seamless integration of ipie with external libraries. We enable distributed Hamiltonian simulations of large systems that otherwise would not fit on a single central processing unit node or graphics processing unit (GPU) card. This development enabled us to compute the interaction energy of a benzene dimer with 84 electrons and 1512 orbitals with multi-GPUs. Using CUDA and cupy for NVIDIA GPUs, ipie supports GPU-accelerated multi-slater determinant trial wavefunctions [Huang et al. arXiv:2406.08314 (2024)] to enable efficient and highly accurate simulations of large-scale systems. This allows for near-exact ground state energies of multi-reference clusters, [Cu2O2]2+ and [Fe2S2(SCH3)4]2−. We also describe implementations of free projection AFQMC, finite temperature AFQMC, AFQMC for electron–phonon systems, and automatic differentiation in AFQMC for calculating physical properties. These advancements position ipie as a leading platform for AFQMC research in quantum chemistry, facilitating more complex and ambitious computational method development and their applications.

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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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Classical and quantum cost of measurement strategies for quantum-enhanced auxiliary field quantum Monte Carlo

Cited by 3 publications

References 66 publications

Modeling Heterogeneous Catalysis Using Quantum Computers: An Academic and Industry Perspective

Modeling Heterogeneous Catalysis Using Quantum Computers: An Academic and Industry Perspective

Improved modularity and new features in `ipie`: Toward even larger AFQMC calculations on CPUs and GPUs at zero and finite temperatures

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

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Product

Resources

About

Classical and quantum cost of measurement strategies for quantum-enhanced auxiliary field quantum Monte Carlo

Cited by 3 publications

References 66 publications

Modeling Heterogeneous Catalysis Using Quantum Computers: An Academic and Industry Perspective

Modeling Heterogeneous Catalysis Using Quantum Computers: An Academic and Industry Perspective

Improved modularity and new features in ipie: Toward even larger AFQMC calculations on CPUs and GPUs at zero and finite temperatures

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

Contact Info

Product

Resources

About

Improved modularity and new features in `ipie`: Toward even larger AFQMC calculations on CPUs and GPUs at zero and finite temperatures