Event Generators for High-Energy Physics Experiments

J. M. Campbell,M. Diefenthaler,Timothy Hobbs,Stefan Höche,Joshua Isaacson,Felix Kling,Stephen Mrenna,J. Reuter,Simone Alioli,J. R. Andersen,C. Andreopoulos,A. M. Ankowski,E. C. Aschenauer,A. Ashkenazi,M. D. Baker,Joshua Barrow,Melissa van Beekveld,Gavin Bewick,S. Bhattacharya,Christian Bierlich,Enrico Bothmann, P. Bredt,A. Broggio,Andrew Buckley,Anja Butter,Jonathan Butterworth, E. P. Byrne,C. M. Carloni Calame,Smita Chakraborty,X. Chen,M. Chiesa,J. T. Childers,J. Cruz-Martinez,James Currie,Neda Darvishi,Mrinal Dasgupta,A. Denner,F. A. Dreyer,S. Dytman,Basem Kamal El-Menoufi,Tim Engel,Silvia Ferrario Ravasio,Daniel G. Figueroa, L. Flower,Jeffrey R. Forshaw,Rikkert Frederix,Alex Friedland,Stefano Frixione,H. Gallagher,K. Gallmeister,S. A. Gardiner,R. Gauld,Jonathan R. Gaunt,A. Gavardi,T. Gehrmann,A. Gehrmann–De Ridder,Leif Gellersen,Walter T. Giele,Stefan Gieseke,Francesco Giuli,E. W. N. Glover,Massimiliano Grazzini,A. Grohsjean,Christian Gütschow,K. Hamilton,Tong Han,R. Hatcher,G. Heinrich,Ilkka Helenius,O. Hen,Valentin Hirschi,Marius Höfer,Jack Holguin,Alexander Huss,P. Ilten,S. Jadach,A. Jentsch,Sarah Jones, W. Ju,Stefan Kallweit,Alexander Karlberg,T. Katori,M. Kerner,C. Kilian, M. M. Kirchgaeßer, S. Das,Max Knobbe,Claudius Krause,Frank Krauss,Jean-Nicolas Lang,J.-N Lang,G. Lee,S. W. Li,M. A. Lim,J. M. Lindert, D. Lombardi,Leif Lönnblad, M. Löschner,N. Lurkin,Lianliang Ma,Pedro A. N. Machado,Vitaly Magerya,Andreas Maier,I. Májer,Fabio Maltoni,Matteo Marcoli, G. Marinelli,M. R. Masouminia,Pierpaolo Mastrolia,Olivier Mattelaer,J. Mazzitelli,Josh Mcfayden,Rok Medves,Peter Meinzinger,J. Mo,Pier Francesco Monni,G. Montagna,Thomas A. Morgan,U. Mosel,Benjamin Philip Nachman,Pavel Nadolsky,R. Nagar,Zoltán Nagy,Davide Napoletano,Paolo Nason, Tobias Neumann,Laurence Nevay,O. Nicrosini,J. Niehues,K. Niewczas,Thorsten Ohl,Giovanni Ossola,V. Pandey,A. Papadopoulou,Andreas Papaefstathiou,Gil Paz,Mathieu Pellen,Giovanni Pelliccioli,Tiziano Peraro,F. Piccinini,L. Pickering,J. Pires,W. Płaczek,Simon Plätzer,Tilman Plehn,Stefano Pozzorini,Stefan Prestel,Christian Preuss,A. C. Price,Seth Quackenbush,Emanuele Re,Daniel Reichelt,Laura Reina,Christian Reuschle,Peter Richardson, Marco Rocco,Noemi Rocco,M. Roda, A. Rodriguez Garcia, S. Roiser,Juan Rojo,Luca Rottoli,Gavin P. Salam,Marek Schoenherr, S. Schuchmann,Steffen Schumann,Robin Schürmann,Ludovic Michel Scyboz,Michael H. Seymour,Frank Siegert,Adrian Signer,Gurpreet Singh Chahal,Andrzej Siódmok,Torbjörn Sjöstrand,Peter Skands,Jennifer M. Smillie,J. T. Sobczyk,Dennis Soldin,D. E. Soper,Alba Soto-Ontoso,Grégory Soyez,Giovanni Stagnitto,J. Tena-Vidal,Oleksandr Tomalak,Francesco Tramontano,Sebastian Trojanowski,Zhoudunming Tu,Sandro Uccirati,T. Ullrich,Yannick Ulrich,Marius Utheim,Andrea Valassi,Andrii Verbytskyi,Rob Verheyen,Michael L. Wagman,Duncan Walker,B. R. Webber,Larry Weinstein, O. White,James Whitehead,Marius Wiesemann,C. Wilkinson,C. Williams,Ramon Winterhalder,C. Wret,K. Xie, Tianzhi Yang,Efe Yazgan,Giulia Zanderighi, S. Zanoli,Korinna Christine Zapp

SciPost physics（2024）

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Abstract

We provide an overview of the status of Monte-Carlo event generators for high-energy particle physics. Guided by the experimental needs and requirements, we highlight areas of active development, and opportunities for future improvements. Particular emphasis is given to physics models and algorithms that are employed across a variety of experiments. These common themes in event generator development lead to a more comprehensive understanding of physics at the highest energies and intensities, and allow models to be tested against a wealth of data that have been accumulated over the past decades. A cohesive approach to event generator development will allow these models to be further improved and systematic uncertainties to be reduced, directly contributing to future experimental success. Event generators are part of a much larger ecosystem of computational tools. They typically involve a number of unknown model parameters that must be tuned to experimental data, while maintaining the integrity of the underlying physics models. Making both these data, and the analyses with which they have been obtained accessible to future users is an essential aspect of open science and data preservation. It ensures the consistency of physics models across a variety of experiments.

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