Automatizing the search for mass resonances using BumpNet

Jean François Arguin; Georges Azuelos; Émile Baril; Ilan Bessudo; Fannie Bilodeau; Maryna Borysova; Shikma Bressler; Samuel Calvet; Julien Donini; Etienne Dreyer; Michael Kwok Lam Chu; Eva Mayer; Ethan Meszaros; Nilotpal Kakati; Bruna Pascual Dias; Joséphine Potdevin; Amit Shkuri; Eitan Sprejer; Muhammad Usman

doi:10.1007/JHEP02(2025)122

Automatizing the search for mass resonances using BumpNet

Jean François Arguin^*, Georges Azuelos, Émile Baril, Ilan Bessudo, Fannie Bilodeau, Maryna Borysova, Shikma Bressler^*, Samuel Calvet, Julien Donini, Etienne Dreyer, Michael Kwok Lam Chu, Eva Mayer, Ethan Meszaros, Nilotpal Kakati, Bruna Pascual Dias, Joséphine Potdevin, Amit Shkuri, Eitan Sprejer, Muhammad Usman

^*Corresponding author for this work

Department of Particle Physics and Astrophysics

Research output: Contribution to journal › Article › peer-review

Abstract

The search for resonant mass bumps in invariant-mass distributions remains a cornerstone strategy for uncovering Beyond the Standard Model (BSM) physics at the Large Hadron Collider (LHC). Traditional methods often rely on predefined functional forms and exhaustive computational and human resources, limiting the scope of tested final states and selections. This work presents BumpNet, a machine learning-based approach leveraging advanced neural network architectures to generalize and enhance the Data-Directed Paradigm (DDP) for resonance searches. Trained on a diverse dataset of smoothly-falling analytical functions and realistic simulated data, BumpNet efficiently predicts statistical significance distributions across varying histogram configurations, including those derived from LHC-like conditions. The network’s performance is validated against idealized likelihood ratio-based tests, showing minimal bias and strong sensitivity in detecting mass bumps across a range of scenarios. Additionally, BumpNet’s application to realistic BSM scenarios highlights its capability to identify subtle signals while managing the look-elsewhere effect. These results underscore BumpNet’s potential to expand the reach of resonance searches, paving the way for more comprehensive explorations of LHC data in future analyses.

Original language	English
Article number	122
Journal	Journal of High Energy Physics
Volume	2025
DOIs	https://doi.org/10.1007/JHEP02(2025)122
Publication status	Published - 19 Feb 2025

Funding

We gratefully acknowledge the support of the Natural Sciences and Engineering Research Council of Canada (NSERC), the Institut de valorisation des donnees IVADO, the Canada First Research Excellence Fund, and the Israeli Science Foundation (ISF, Grant No. 2382/24). We also extend our gratitude to the Krenter-Perinot Center for High-Energy Particle Physics, the Shimon and Golde Picker-Weizmann Annual Grant, and the Sir Charles Clore Prize for their support. A special thanks is extended to Martin Kushner Schnur for his invaluable contribution to this research.

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics

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Cite this

Arguin, J. F., Azuelos, G., Baril, É., Bessudo, I., Bilodeau, F., Borysova, M., Bressler, S., Calvet, S., Donini, J., Dreyer, E., Chu, M. K. L., Mayer, E., Meszaros, E., Kakati, N., Dias, B. P., Potdevin, J., Shkuri, A., Sprejer, E., & Usman, M. (2025). Automatizing the search for mass resonances using BumpNet. Journal of High Energy Physics, 2025, Article 122. https://doi.org/10.1007/JHEP02(2025)122

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title = "Automatizing the search for mass resonances using BumpNet",

abstract = "The search for resonant mass bumps in invariant-mass distributions remains a cornerstone strategy for uncovering Beyond the Standard Model (BSM) physics at the Large Hadron Collider (LHC). Traditional methods often rely on predefined functional forms and exhaustive computational and human resources, limiting the scope of tested final states and selections. This work presents BumpNet, a machine learning-based approach leveraging advanced neural network architectures to generalize and enhance the Data-Directed Paradigm (DDP) for resonance searches. Trained on a diverse dataset of smoothly-falling analytical functions and realistic simulated data, BumpNet efficiently predicts statistical significance distributions across varying histogram configurations, including those derived from LHC-like conditions. The network{\textquoteright}s performance is validated against idealized likelihood ratio-based tests, showing minimal bias and strong sensitivity in detecting mass bumps across a range of scenarios. Additionally, BumpNet{\textquoteright}s application to realistic BSM scenarios highlights its capability to identify subtle signals while managing the look-elsewhere effect. These results underscore BumpNet{\textquoteright}s potential to expand the reach of resonance searches, paving the way for more comprehensive explorations of LHC data in future analyses.",

author = "Arguin, \{Jean Fran{\c c}ois\} and Georges Azuelos and {\'E}mile Baril and Ilan Bessudo and Fannie Bilodeau and Maryna Borysova and Shikma Bressler and Samuel Calvet and Julien Donini and Etienne Dreyer and Chu, \{Michael Kwok Lam\} and Eva Mayer and Ethan Meszaros and Nilotpal Kakati and Dias, \{Bruna Pascual\} and Jos{\'e}phine Potdevin and Amit Shkuri and Eitan Sprejer and Muhammad Usman",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

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doi = "10.1007/JHEP02(2025)122",

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Arguin, JF, Azuelos, G, Baril, É, Bessudo, I, Bilodeau, F, Borysova, M , Bressler, S, Calvet, S, Donini, J, Dreyer, E , Chu, MKL, Mayer, E, Meszaros, E, Kakati, N, Dias, BP, Potdevin, J, Shkuri, A, Sprejer, E & Usman, M 2025, 'Automatizing the search for mass resonances using BumpNet', Journal of High Energy Physics, vol. 2025, 122. https://doi.org/10.1007/JHEP02(2025)122

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T1 - Automatizing the search for mass resonances using BumpNet

AU - Arguin, Jean François

AU - Azuelos, Georges

AU - Baril, Émile

AU - Bessudo, Ilan

AU - Bilodeau, Fannie

AU - Borysova, Maryna

AU - Bressler, Shikma

AU - Calvet, Samuel

AU - Donini, Julien

AU - Dreyer, Etienne

AU - Chu, Michael Kwok Lam

AU - Mayer, Eva

AU - Meszaros, Ethan

AU - Kakati, Nilotpal

AU - Dias, Bruna Pascual

AU - Potdevin, Joséphine

AU - Shkuri, Amit

AU - Sprejer, Eitan

AU - Usman, Muhammad

PY - 2025/2/19

Y1 - 2025/2/19

N2 - The search for resonant mass bumps in invariant-mass distributions remains a cornerstone strategy for uncovering Beyond the Standard Model (BSM) physics at the Large Hadron Collider (LHC). Traditional methods often rely on predefined functional forms and exhaustive computational and human resources, limiting the scope of tested final states and selections. This work presents BumpNet, a machine learning-based approach leveraging advanced neural network architectures to generalize and enhance the Data-Directed Paradigm (DDP) for resonance searches. Trained on a diverse dataset of smoothly-falling analytical functions and realistic simulated data, BumpNet efficiently predicts statistical significance distributions across varying histogram configurations, including those derived from LHC-like conditions. The network’s performance is validated against idealized likelihood ratio-based tests, showing minimal bias and strong sensitivity in detecting mass bumps across a range of scenarios. Additionally, BumpNet’s application to realistic BSM scenarios highlights its capability to identify subtle signals while managing the look-elsewhere effect. These results underscore BumpNet’s potential to expand the reach of resonance searches, paving the way for more comprehensive explorations of LHC data in future analyses.

AB - The search for resonant mass bumps in invariant-mass distributions remains a cornerstone strategy for uncovering Beyond the Standard Model (BSM) physics at the Large Hadron Collider (LHC). Traditional methods often rely on predefined functional forms and exhaustive computational and human resources, limiting the scope of tested final states and selections. This work presents BumpNet, a machine learning-based approach leveraging advanced neural network architectures to generalize and enhance the Data-Directed Paradigm (DDP) for resonance searches. Trained on a diverse dataset of smoothly-falling analytical functions and realistic simulated data, BumpNet efficiently predicts statistical significance distributions across varying histogram configurations, including those derived from LHC-like conditions. The network’s performance is validated against idealized likelihood ratio-based tests, showing minimal bias and strong sensitivity in detecting mass bumps across a range of scenarios. Additionally, BumpNet’s application to realistic BSM scenarios highlights its capability to identify subtle signals while managing the look-elsewhere effect. These results underscore BumpNet’s potential to expand the reach of resonance searches, paving the way for more comprehensive explorations of LHC data in future analyses.

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U2 - 10.1007/JHEP02(2025)122

DO - 10.1007/JHEP02(2025)122

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AN - SCOPUS:86000026421

SN - 1029-8479

VL - 2025

JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

M1 - 122

ER -

Automatizing the search for mass resonances using BumpNet

Abstract

Funding

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