Quantum simulation of realistic materials in first quantization using non-local pseudopotentials

Dominic W. Berry; Nicholas C. Rubin; Ahmed O. Elnabawy; Gabriele Ahlers; A. Eugene DePrince III; Joonho Lee; Christian Gogolin; Ryan Babbush

doi:10.1038/s41534-024-00896-9

Quantum simulation of realistic materials in first quantization using non-local pseudopotentials

Dominic W. Berry^*, Nicholas C. Rubin^*, Ahmed O. Elnabawy, Gabriele Ahlers, A. Eugene DePrince III, Joonho Lee, Christian Gogolin, Ryan Babbush^*

^*Corresponding author for this work

School of Mathematical and Physical Sciences

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

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Abstract

This paper improves and demonstrates the usefulness of the first quantized plane-wave algorithms for the quantum simulation of electronic structure. We describe our quantum algorithm for first quantized simulation that accurately includes pseudopotentials. We focus on the Goedecker-Tetter-Hutter pseudopotential, and despite its complicated form, we block encode the associated operator without significantly increasing the overall cost of quantum simulation. This is surprising since simulating the nuclear potential is much simpler without pseudopotentials, yet is still the bottleneck. We also generalize prior methods to enable the simulation of materials with non-cubic unit cells, which requires nontrivial modifications. Finally, we combine these techniques to estimate block-encoding costs for commercially relevant instances of heterogeneous catalysis (e.g. carbon monoxide adsorption) and compare to the quantum resources needed to simulate materials in second quantization. We conclude that for computational cells with many particles, first quantization often requires meaningfully less spacetime volume.

Original language	English
Article number	130
Pages (from-to)	1-29
Number of pages	29
Journal	npj Quantum Information
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41534-024-00896-9
Publication status	Published - Dec 2024

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10.1038/s41534-024-00896-9Licence: CC BY-NC-ND

Publisher version (open access)Final published version, 1.29 MBLicence: CC BY-NC-ND

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title = "Quantum simulation of realistic materials in first quantization using non-local pseudopotentials",

abstract = "This paper improves and demonstrates the usefulness of the first quantized plane-wave algorithms for the quantum simulation of electronic structure. We describe our quantum algorithm for first quantized simulation that accurately includes pseudopotentials. We focus on the Goedecker-Tetter-Hutter pseudopotential, and despite its complicated form, we block encode the associated operator without significantly increasing the overall cost of quantum simulation. This is surprising since simulating the nuclear potential is much simpler without pseudopotentials, yet is still the bottleneck. We also generalize prior methods to enable the simulation of materials with non-cubic unit cells, which requires nontrivial modifications. Finally, we combine these techniques to estimate block-encoding costs for commercially relevant instances of heterogeneous catalysis (e.g. carbon monoxide adsorption) and compare to the quantum resources needed to simulate materials in second quantization. We conclude that for computational cells with many particles, first quantization often requires meaningfully less spacetime volume.",

author = "Berry, {Dominic W.} and Rubin, {Nicholas C.} and Elnabawy, {Ahmed O.} and Gabriele Ahlers and {DePrince III}, {A. Eugene} and Joonho Lee and Christian Gogolin and Ryan Babbush",

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year = "2024",

month = dec,

doi = "10.1038/s41534-024-00896-9",

language = "English",

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AU - Berry, Dominic W.

AU - Rubin, Nicholas C.

AU - Elnabawy, Ahmed O.

AU - Ahlers, Gabriele

AU - DePrince III, A. Eugene

AU - Lee, Joonho

AU - Gogolin, Christian

AU - Babbush, Ryan

N1 - © The Author(s) 2024. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

PY - 2024/12

Y1 - 2024/12

N2 - This paper improves and demonstrates the usefulness of the first quantized plane-wave algorithms for the quantum simulation of electronic structure. We describe our quantum algorithm for first quantized simulation that accurately includes pseudopotentials. We focus on the Goedecker-Tetter-Hutter pseudopotential, and despite its complicated form, we block encode the associated operator without significantly increasing the overall cost of quantum simulation. This is surprising since simulating the nuclear potential is much simpler without pseudopotentials, yet is still the bottleneck. We also generalize prior methods to enable the simulation of materials with non-cubic unit cells, which requires nontrivial modifications. Finally, we combine these techniques to estimate block-encoding costs for commercially relevant instances of heterogeneous catalysis (e.g. carbon monoxide adsorption) and compare to the quantum resources needed to simulate materials in second quantization. We conclude that for computational cells with many particles, first quantization often requires meaningfully less spacetime volume.

AB - This paper improves and demonstrates the usefulness of the first quantized plane-wave algorithms for the quantum simulation of electronic structure. We describe our quantum algorithm for first quantized simulation that accurately includes pseudopotentials. We focus on the Goedecker-Tetter-Hutter pseudopotential, and despite its complicated form, we block encode the associated operator without significantly increasing the overall cost of quantum simulation. This is surprising since simulating the nuclear potential is much simpler without pseudopotentials, yet is still the bottleneck. We also generalize prior methods to enable the simulation of materials with non-cubic unit cells, which requires nontrivial modifications. Finally, we combine these techniques to estimate block-encoding costs for commercially relevant instances of heterogeneous catalysis (e.g. carbon monoxide adsorption) and compare to the quantum resources needed to simulate materials in second quantization. We conclude that for computational cells with many particles, first quantization often requires meaningfully less spacetime volume.

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Quantum simulation of realistic materials in first quantization using non-local pseudopotentials

Abstract

Bibliographical note

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Griffith Led: Heisenberg-limited lasers: building the revolution

UTS led: Pushing the digital limits in quantum simulation for advanced manufacturing

Quantum algorithms for quantum chemistry

Cite this

Quantum simulation of realistic materials in first quantization using non-local pseudopotentials

Abstract

Bibliographical note

Access to Document

Other files and links

Projects

Griffith Led: Heisenberg-limited lasers: building the revolution

UTS led: Pushing the digital limits in quantum simulation for advanced manufacturing

Quantum algorithms for quantum chemistry

Cite this