Exploiting jet binning to identify the initial state of high-mass resonances

TL;DR

This paper introduces a model-independent jet binning technique at the LHC to determine the initial state of high-mass resonances, aiding in understanding their production mechanisms with minimal theoretical uncertainties.

Contribution

It proposes a novel, effective field theory-based jet binning method to distinguish quark and gluon initial states for high-mass resonances, applicable with small event samples.

Findings

Jet binning cut of several tens of GeV effectively discriminates initial states.

Method achieves comparable cross sections in different jet bins.

The approach is demonstrated with a 750 GeV scalar resonance example.

Abstract

If a new high-mass resonance is discovered at the Large Hadron Collider, model-independent techniques to identify the production mechanism will be crucial to understand its nature and effective couplings to Standard Model particles. We present a powerful and model-independent method to infer the initial state in the production of any high-mass color-singlet system by using a tight veto on accompanying hadronic jets to divide the data into two mutually exclusive event samples (jet bins). For a resonance of several hundred GeV, the jet binning cut needed to discriminate quark and gluon initial states is in the experimentally accessible range of several tens of GeV. It also yields comparable cross sections for both bins, making this method viable already with the small event samples available shortly after a discovery. Theoretically, the method is made feasible by utilizing an effective field theory setup to compute the jet cut dependence precisely and model independently and to systematically control all sources of theoretical uncertainties in the jet binning, as well as their correlations. We use a 750 GeV scalar resonance as an example to demonstrate the viability of our method.