Energy Correlators: A Journey From Theory to Experiment

TL;DR

This paper reviews recent advances in understanding energy correlators in collider physics, highlighting their theoretical significance and experimental measurement, and emphasizing their potential to connect formal quantum field theory with real-world collider data.

Contribution

It provides a comprehensive survey of energy flow operators and their correlators, bridging formal theory and collider phenomenology, and encouraging interdisciplinary collaboration.

Findings

Energy correlators can be measured in collider experiments.

They connect quantum field theory with experimental observables.

Potential to deepen understanding of the Standard Model and new physics.

Abstract

Collider experiments offer a unique opportunity to explore the Standard Model (SM), and to search for new physics, new interactions, and new principles of nature. The theoretical abstraction of a collider, namely the study of correlations in asymptotic fluxes, provides one of the most basic examples of an observable in quantum field theory (QFT) and quantum gravity. Energy flux is described in QFT by energy flow operators, a particular example of light-ray operators. In addition to their central role in the theoretical description of collider physics, energy flow operators play an important role in diverse areas of formal QFT and gravity, providing a connection between real world collider phenomenology, and the deep underlying principles of QFT. Recently it has become possible to measure correlation functions of energy flow operators in a wide variety of collider experiments, providing an exciting new connection between collider physics and formal theory. In this review, we provide a survey of recent progress in our understanding of energy operators and their correlators, highlighting their importance in both formal theory and collider phenomenology, and in particular, their great potential for bridging these areas to provide new ways to understand the real world. We intend this article as a resource for both formal theorists interested in understanding how light-ray operators are being applied in particle and nuclear physics, as well as for experimentalists interested in the theoretical motivation for these observables. Most importantly, we aim to stimulate further interaction between the formal, phenomenological and experimental communities through the common lens of energy correlators.