Detector and Beamline Simulation for Next-Generation High Energy Physics Experiments
High Energy Physics - Experiment
2022-04-22 v3 Computational Physics
Abstract
The success of high energy physics programs relies heavily on accurate detector simulations and beam interaction modeling. The increasingly complex detector geometries and beam dynamics require sophisticated techniques in order to meet the demands of current and future experiments. Common software tools used today are unable to fully utilize modern computational resources, while data-recording rates are often orders of magnitude larger than what can be produced via simulation. In this paper, we describe the state, current and future needs of high energy physics detector and beamline simulations and related challenges, and we propose a number of possible ways to address them.
Cite
@article{arxiv.2203.07614,
title = {Detector and Beamline Simulation for Next-Generation High Energy Physics Experiments},
author = {Sunanda Banerjee and D. N. Brown and David N. Brown and Paolo Calafiura and Jacob Calcutt and Philippe Canal and Miriam Diamond and Daniel Elvira and Thomas Evans and Renee Fatemi and Krzysztof Genser and Robert Hatcher and Alexander Himmel and Seth R. Johnson and Soon Yung Jun and Michael Kelsey and Evangelos Kourlitis and Robert K. Kutschke and Guilherme Lima and Kevin Lynch and Kendall Mahn and Zachary Marshall and Michael Mooney and Adam Para and Vincent R. Pascuzzi and Kevin Pedro and Oleg Samoylov and Erica Snider and Pavel Snopok and Matthew Szydagis and Hans Wenzel and Leigh H. Whitehead and Tingjun Yang and Julia Yarba},
journal= {arXiv preprint arXiv:2203.07614},
year = {2022}
}
Comments
Contribution to Snowmass 2021