All is More: Energy Flow Networks for Jet Quenching

TL;DR

This paper introduces energy flow networks for jet quenching analysis, demonstrating their superior performance in distinguishing jet modifications due to quark-gluon plasma effects, especially when combined with physics-motivated observables.

Contribution

The study develops and applies energy flow networks with observable enhancements, achieving state-of-the-art jet discrimination performance in heavy-ion collision scenarios.

Findings

Energy flow networks outperform traditional baselines in jet discrimination.

Observable-enhanced networks achieve ROC AUC of approximately 0.83.

Moment energy flow networks offer comparable accuracy with simpler interpretability.

Abstract

Jet quenching, the modification of jets by the quark-gluon plasma in heavy-ion collisions, provides a sensitive probe of the properties of the medium. A jet-by-jet discrimination study between proton-proton and lead-lead jets using energy flow networks and simple baselines, explicitly retaining medium response and underlying event contamination is presented. As references, linear discriminants and neural networks have been trained on high-level observables such as $N$-subjettiness and energy flow polynomials, including an extended energy flow polynomial set, in order to quantify the achievable performance without constituent-level learning. Energy flow networks are then trained on jet constituents and extended to observable-enhanced energy flow networks that concatenate standardized $N$-subjettiness and/or energy flow polynomials to the energy flow network latent space. In the realistic scenario, including both underlying event contamination and medium response, observable-enhanced energy flow networks set state-of-the-art performance with receiver operating characteristic area under the curve of $\simeq 0.83$, improving markedly over linear and non-linear baselines and previous work with different architectures. Finally, results from moment energy flow networks, an energy flow network variant that attains comparable area under the curve with a substantially more compact and interpretable latent space are shown. These results establish energy-flow-network-based approaches (especially when enhanced with physics-motivated observables) as practical and robust tools for jet-quenching studies.