Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms

Benran Zhang; Daniel Weinberg; Chih-En Hsu; Aaron Altman; Yuming Shi; James White; Derek Vigil-Fowler; Steven Louie; Jack Deslippe; Felipe da Jornada; Zhenglu Li; Mauro Del Ben

doi:10.1145/3712285.3772093

Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms

Benran Zhang
, Daniel Weinberg
, Chih-En Hsu
, Aaron Altman
, Yuming Shi
, James White
, Derek Vigil-Fowler
, Steven Louie
, Jack Deslippe
, Felipe da Jornada
, Zhenglu Li
, Mauro Del Ben

Computational Science

Research output: Contribution to conference › Paper

Abstract

Advanced ab initio materials simulations face growing challenges as increasing systems and phenomena complexity requires higher accuracy, driving up computational demands. Quantum many-body GW methods are state-of-the-art for treating electronic excited states and couplings but often hindered due to the costly numerical complexity. Here, we present innovative implementations of advanced GW methods within the BerkeleyGW package, enabling large-scale simulations on Frontier and Aurora exascale platforms. Our approach demonstrates exceptional versatility for complex heterogeneous systems with up to 17,574 atoms, along with achieving true performance portability across GPU architectures. We demonstrate excellent strong and weak scaling to thousands of nodes, reaching double-precision core-kernel performance of 1.069 ExaFLOP/s on Frontier (9,408 nodes) and 707.52 PetaFLOP/s on Aurora (9,600 nodes), corresponding to 59.45% and 48.79% of peak, respectively. Our work demonstrates a breakthrough in utilizing exascale computing for quantum materials simulations, delivering unprecedented predictive capabilities for rational designs of future quantum technologies.

Original language	American English
Pages	48-59
Number of pages	12
DOIs	https://doi.org/10.1145/3712285.3772093
State	Published - 2025
Event	International Conference for High Performance Computing, Networking, Storage and Analysis - St. Louis, Missour Duration: 16 Nov 2025 → 21 Nov 2025

Conference

Conference	International Conference for High Performance Computing, Networking, Storage and Analysis
City	St. Louis, Missour
Period	16/11/25 → 21/11/25

NLR Publication Number

NLR/CP-2C00-98976

Keywords

electron excited states
GW method and GW perturbation theory
many-body interactions
quantum materials

Access to Document

10.1145/3712285.3772093

Cite this

Zhang, B., Weinberg, D., Hsu, C.-E., Altman, A., Shi, Y., White, J., Vigil-Fowler, D., Louie, S., Deslippe, J., da Jornada, F., Li, Z., & Del Ben, M. (2025). Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms. 48-59. Paper presented at International Conference for High Performance Computing, Networking, Storage and Analysis, St. Louis, Missour. https://doi.org/10.1145/3712285.3772093

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title = "Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms",

abstract = "Advanced ab initio materials simulations face growing challenges as increasing systems and phenomena complexity requires higher accuracy, driving up computational demands. Quantum many-body GW methods are state-of-the-art for treating electronic excited states and couplings but often hindered due to the costly numerical complexity. Here, we present innovative implementations of advanced GW methods within the BerkeleyGW package, enabling large-scale simulations on Frontier and Aurora exascale platforms. Our approach demonstrates exceptional versatility for complex heterogeneous systems with up to 17,574 atoms, along with achieving true performance portability across GPU architectures. We demonstrate excellent strong and weak scaling to thousands of nodes, reaching double-precision core-kernel performance of 1.069 ExaFLOP/s on Frontier (9,408 nodes) and 707.52 PetaFLOP/s on Aurora (9,600 nodes), corresponding to 59.45\% and 48.79\% of peak, respectively. Our work demonstrates a breakthrough in utilizing exascale computing for quantum materials simulations, delivering unprecedented predictive capabilities for rational designs of future quantum technologies.",

keywords = "electron excited states, GW method and GW perturbation theory, many-body interactions, quantum materials",

author = "Benran Zhang and Daniel Weinberg and Chih-En Hsu and Aaron Altman and Yuming Shi and James White and Derek Vigil-Fowler and Steven Louie and Jack Deslippe and \{da Jornada\}, Felipe and Zhenglu Li and \{Del Ben\}, Mauro",

year = "2025",

doi = "10.1145/3712285.3772093",

language = "American English",

pages = "48--59",

note = "International Conference for High Performance Computing, Networking, Storage and Analysis ; Conference date: 16-11-2025 Through 21-11-2025",

}

Zhang, B, Weinberg, D, Hsu, C-E, Altman, A, Shi, Y, White, J, Vigil-Fowler, D, Louie, S, Deslippe, J, da Jornada, F, Li, Z & Del Ben, M 2025, 'Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms', Paper presented at International Conference for High Performance Computing, Networking, Storage and Analysis, St. Louis, Missour, 16/11/25 - 21/11/25 pp. 48-59. https://doi.org/10.1145/3712285.3772093

TY - CONF

T1 - Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms

AU - Zhang, Benran

AU - Weinberg, Daniel

AU - Hsu, Chih-En

AU - Altman, Aaron

AU - Shi, Yuming

AU - White, James

AU - Vigil-Fowler, Derek

AU - Louie, Steven

AU - Deslippe, Jack

AU - da Jornada, Felipe

AU - Li, Zhenglu

AU - Del Ben, Mauro

PY - 2025

Y1 - 2025

N2 - Advanced ab initio materials simulations face growing challenges as increasing systems and phenomena complexity requires higher accuracy, driving up computational demands. Quantum many-body GW methods are state-of-the-art for treating electronic excited states and couplings but often hindered due to the costly numerical complexity. Here, we present innovative implementations of advanced GW methods within the BerkeleyGW package, enabling large-scale simulations on Frontier and Aurora exascale platforms. Our approach demonstrates exceptional versatility for complex heterogeneous systems with up to 17,574 atoms, along with achieving true performance portability across GPU architectures. We demonstrate excellent strong and weak scaling to thousands of nodes, reaching double-precision core-kernel performance of 1.069 ExaFLOP/s on Frontier (9,408 nodes) and 707.52 PetaFLOP/s on Aurora (9,600 nodes), corresponding to 59.45% and 48.79% of peak, respectively. Our work demonstrates a breakthrough in utilizing exascale computing for quantum materials simulations, delivering unprecedented predictive capabilities for rational designs of future quantum technologies.

AB - Advanced ab initio materials simulations face growing challenges as increasing systems and phenomena complexity requires higher accuracy, driving up computational demands. Quantum many-body GW methods are state-of-the-art for treating electronic excited states and couplings but often hindered due to the costly numerical complexity. Here, we present innovative implementations of advanced GW methods within the BerkeleyGW package, enabling large-scale simulations on Frontier and Aurora exascale platforms. Our approach demonstrates exceptional versatility for complex heterogeneous systems with up to 17,574 atoms, along with achieving true performance portability across GPU architectures. We demonstrate excellent strong and weak scaling to thousands of nodes, reaching double-precision core-kernel performance of 1.069 ExaFLOP/s on Frontier (9,408 nodes) and 707.52 PetaFLOP/s on Aurora (9,600 nodes), corresponding to 59.45% and 48.79% of peak, respectively. Our work demonstrates a breakthrough in utilizing exascale computing for quantum materials simulations, delivering unprecedented predictive capabilities for rational designs of future quantum technologies.

KW - electron excited states

KW - GW method and GW perturbation theory

KW - many-body interactions

KW - quantum materials

U2 - 10.1145/3712285.3772093

DO - 10.1145/3712285.3772093

M3 - Paper

SP - 48

EP - 59

T2 - International Conference for High Performance Computing, Networking, Storage and Analysis

Y2 - 16 November 2025 through 21 November 2025

ER -

Advancing Quantum Many-Body GW Calculations on Exascale Supercomputing Platforms

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