Report of the Snowmass 2021 Topical Group on Lattice Gauge Theory

Zohreh Davoudi; Ethan T Neil; Christian W Bauer; Tanmoy Bhattacharya; Thomas Blum; Peter Boyle; Richard C Brower; Simon Catterall; Norman H Christ; Vincenzo Cirigliano; Gilberto Colangelo; Carleton DeTar; William Detmold; Robert G Edwards; Aida X El-Khadra; Steven Gottlieb; Rajan Gupta; Daniel C Hackett; Anna Hasenfratz; Taku Izubuchi; William I Jay; Luchang Jin; Christopher Kelly; Andreas S Kronfeld; Christoph Lehner; Huey-Wen Lin; Meifeng Lin; Andrew T Lytle; Stefan Meinel; Yannick Meurice; Swagato Mukherjee; Amy Nicholson; Sasa Prelovsek; Martin J Savage; Phiala E Shanahan; Ruth S Van De Water; Michael L Wagman; Oliver Witzel

doi:10.48550/arxiv.2209.10758

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Report of the Snowmass 2021 Topical Group on Lattice Gauge Theory

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Report of the Snowmass 2021 Topical Group on Lattice Gauge Theory

Zohreh Davoudi, Ethan T Neil, Christian W Bauer, Tanmoy Bhattacharya, Thomas Blum, Peter Boyle, Richard C Brower, Simon Catterall, Norman H Christ, Vincenzo Cirigliano, …

ArXiv.org

Cornell University

09/21/2022

DOI: 10.48550/arxiv.2209.10758

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Preprint (Author's original)This preprint has not been evaluated by subject experts through peer review. Preprints may undergo extensive changes and/or become peer-reviewed journal articles. Open Access

Abstract

Lattice gauge theory continues to be a powerful theoretical and computational approach to simulating strongly interacting quantum field theories, whose applications permeate almost all disciplines of modern-day research in High-Energy Physics. Whether it is to enable precision quark- and lepton-flavor physics, to uncover signals of new physics in nucleons and nuclei, to elucidate hadron structure and spectrum, to serve as a numerical laboratory to reach beyond the Standard Model, or to invent and improve state-of-the-art computational paradigms, the lattice-gauge-theory program is in a prime position to impact the course of developments and enhance discovery potential of a vibrant experimental program in High-Energy Physics over the coming decade. This projection is based on abundant successful results that have emerged using lattice gauge theory over the years: on continued improvement in theoretical frameworks and algorithmic suits; on the forthcoming transition into the exascale era of high-performance computing; and on a skillful, dedicated, and organized community of lattice gauge theorists in the U.S. and worldwide. The prospects of this effort in pushing the frontiers of research in High-Energy Physics have recently been studied within the U.S. decadal Particle Physics Planning Exercise (Snowmass 2021), and the conclusions are summarized in this Topical Report.

Details

Title: Subtitle: Report of the Snowmass 2021 Topical Group on Lattice Gauge Theory
Creators: Zohreh Davoudi
Ethan T Neil
Christian W Bauer
Tanmoy Bhattacharya
Thomas Blum
Peter Boyle
Richard C Brower
Simon Catterall
Norman H Christ
Vincenzo Cirigliano
Gilberto Colangelo
Carleton DeTar
William Detmold
Robert G Edwards
Aida X El-Khadra
Steven Gottlieb
Rajan Gupta
Daniel C Hackett
Anna Hasenfratz
Taku Izubuchi
William I Jay
Luchang Jin
Christopher Kelly
Andreas S Kronfeld
Christoph Lehner
Huey-Wen Lin
Meifeng Lin
Andrew T Lytle
Stefan Meinel
Yannick Meurice
Swagato Mukherjee
Amy Nicholson
Sasa Prelovsek
Martin J Savage
Phiala E Shanahan
Ruth S Van De Water
Michael L Wagman
Oliver Witzel
Resource Type: Preprint
Publication Details: ArXiv.org
Publisher: Cornell University
DOI: 10.48550/arxiv.2209.10758
ISSN: 2331-8422
Format: PDF
Number of pages: 57
Comment: Submitted to the Proceedings of the US Community Study on the Future of Particle Physics (Snowmass 2021). Topical Group Report for TF05 - Lattice Gauge Theory
Language: English
Date posted: 09/21/2022
Academic Unit: Physics and Astronomy
Record Identifier: 9984442204302771

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