Event generators for high-energy physics experiments

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

doi:10.21468/scipostphys.16.5.130

Cited by 16 publications

(1 citation statement)

References 1,416 publications

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“…Almost all collider tests of the Standard Model (SM) of particle physics rely on predictions obtained using event generators [1,2]. An important part of these tests is the estimation of uncertainties on those predictions, which can often be obtained by varying input parameters to the event generator.…”

Section: Introductionmentioning

confidence: 99%

Reweighting Monte Carlo predictions and automated fragmentation variations in Pythia 8

Bierlich,

Ilten,

Menzo

et al. 2024

SciPost Phys.

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This work reports on a method for uncertainty estimation in simulated collider-event predictions. The method is based on a Monte Carlo-veto algorithm, and extends previous work on uncertainty estimates in parton showers by including uncertainty estimates for the Lund string-fragmentation model. This method is advantageous from the perspective of simulation costs: a single ensemble of generated events can be reinterpreted as though it was obtained using a different set of input parameters, where each event now is accompanied with a corresponding weight. This allows for a robust exploration of the uncertainties arising from the choice of input model parameters, without the need to rerun full simulation pipelines for each input parameter choice. Such explorations are important when determining the sensitivities of precision physics measurements. Accompanying code is available at https://gitlab.com/uchep/mlhad-weights-validation.

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Section: Introductionmentioning

confidence: 99%

Reweighting Monte Carlo predictions and automated fragmentation variations in Pythia 8

Bierlich,

Ilten,

Menzo

et al. 2024

SciPost Phys.

Self Cite

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Two-loop integrals for $$ t\overline{t} $$+jet production at hadron colliders in the leading colour approximation

Badger,

Becchetti,

Giraudo

et al. 2024

J. High Energ. Phys.

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We compute the differential equations for the two remaining integral topologies contributing to the leading colour two-loop amplitudes for pp → $$ t\overline{t}j $$ t t ¯ j . We derive differential equations for the master integrals by solving the integration-by-parts identities over finite fields. Of the two systems of differential equations, one is presented in canonical ‘d log’ form, while the other is found to have an elliptic sector. For the elliptic topology we identify the relevant elliptic curve, and present the differential equations in a more general form which depends quadratically on ε and contains non-logarithmic one-forms in addition to the canonical d log’s. We solve the systems of differential equations numerically using generalised series expansions with the boundary terms obtained using the auxiliary mass flow method. A summary of all one-loop and two-loop planar topologies is presented including the list of alphabet letters for the ‘d log’ form systems and high-precision boundary values.

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NLO+NLL′ accurate predictions for three-jet event shapes in hadronic Higgs decays

Gehrmann-De Ridder,

Preuss,

Reichelt

et al. 2024

J. High Energ. Phys.

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We present resummed predictions at next-to-leading logarithmic accuracy matched to the exact next-to-leading order results for a set of classical event-shape observables in hadronic Higgs decays, i.e., for the channels H → gg and H → $$ b\overline{b} $$ b b ¯ . We furthermore consider soft-drop grooming of the hadronic final states and derive corresponding NLO+NLL′ predictions for the groomed thrust observable. Differences in the QCD radiation pattern of gluon- and quark-initiated final states are imprinted in the event-shape distributions, offering separation power for the two decay channels. In particular, we show that ungroomed event shapes in H → gg decays develop a considerably harder spectrum than in H → $$ b\overline{b} $$ b b ¯ decays. We highlight that soft-drop grooming can substantially alter this behaviour, unless rather inclusive grooming parameters are chosen.

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Event generators for high-energy physics experiments

Cited by 16 publications

References 1,416 publications

Reweighting Monte Carlo predictions and automated fragmentation variations in Pythia 8

Reweighting Monte Carlo predictions and automated fragmentation variations in Pythia 8

Two-loop integrals for $$ t\overline{t} $$+jet production at hadron colliders in the leading colour approximation

NLO+NLL′ accurate predictions for three-jet event shapes in hadronic Higgs decays

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