Scalar Relativistic All-Electron and Pseudopotential Ab Initio Study of a Minimal Nitrogenase [Fe(SH)4H]− Model Employing Coupled-Cluster and Auxiliary-Field Quantum Monte Carlo Many-Body Methods

Vysotskiy, Victor P.; Filippi, Claudia; Ryde, Ulf

doi:10.1021/acs.jpca.3c05808

J. Phys. Chem. A

2024

DOI: 10.1021/acs.jpca.3c05808

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Scalar Relativistic All-Electron and Pseudopotential Ab Initio Study of a Minimal Nitrogenase [Fe(SH)₄H]⁻ Model Employing Coupled-Cluster and Auxiliary-Field Quantum Monte Carlo Many-Body Methods

Victor P. Vysotskiy,

Claudia Filippi,

Ulf Ryde

Abstract: Nitrogenase is the only enzyme that can cleave the triple bond in N 2 , making nitrogen available to organisms. The detailed mechanism of this enzyme is currently not known, and computational studies are complicated by the fact that different density functional theory (DFT) methods give very different energetic results for calculations involving nitrogenase models. Recently, we designed a [Fe(SH) 4 H] − model with the fifth proton binding either to Fe or S to mimic different possible protonation states of the … Show more

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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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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

View full text Add to dashboard Cite

show abstract

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Scalar Relativistic All-Electron and Pseudopotential Ab Initio Study of a Minimal Nitrogenase [Fe(SH)₄H]⁻ Model Employing Coupled-Cluster and Auxiliary-Field Quantum Monte Carlo Many-Body Methods

Cited by 1 publication

References 133 publications

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

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

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Scalar Relativistic All-Electron and Pseudopotential Ab Initio Study of a Minimal Nitrogenase [Fe(SH)4H]− Model Employing Coupled-Cluster and Auxiliary-Field Quantum Monte Carlo Many-Body Methods

Cited by 1 publication

References 133 publications

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

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

Contact Info

Product

Resources

About

Scalar Relativistic All-Electron and Pseudopotential Ab Initio Study of a Minimal Nitrogenase [Fe(SH)₄H]⁻ Model Employing Coupled-Cluster and Auxiliary-Field Quantum Monte Carlo Many-Body Methods

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

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