Radion Candidate for the LHC Diphoton Resonance

TL;DR

This paper investigates a scalar radion candidate within an extended Randall-Sundrum model as a potential explanation for the LHC diphoton excess, highlighting its unique coupling features and compatibility with null search results.

Contribution

It proposes a radion from an extended Randall-Sundrum model as a novel candidate explaining the diphoton resonance with exotic coupling behavior.

Findings

A scalar with specific gluon and photon couplings can explain the diphoton excess.

The extended Randall-Sundrum model can produce a radion with the required properties.

The radion candidate aligns with null results in other search channels.

Abstract

The recent observation of a modest excess in diphoton final states at the LHC, by both the ATLAS and CMS Collaborations, has sparked off the expected race among theorists to find the right explanation for this proto-resonance, assuming that the signal will survive and not prove to be yet another statistical fluctuation. We carry out a general analysis of this `signal' in the case of a scalar which couples only to pairs of gluons (for production) and photons (for diphoton decay modes), and establish that an explanation of the observed resonance, taken together with the null results of new physics searches in all the other channels, requires a scalar with rather exotic behaviour. We then demonstrate that a fairly simple-minded extension of the minimal Randall-Sundrum model can yield a radion candidate which might reproduce this exotic behaviour.