Threshold enhancement of diphoton resonances

TL;DR

This paper explores how threshold effects can significantly enhance diphoton resonance signals, providing a novel explanation for the 750 GeV excess observed at the LHC through specific particle loop mechanisms.

Contribution

It introduces the concept of threshold enhancement in diphoton resonances and applies it to models like the MSSM and two Higgs doublet models, explaining large signals without large particle multiplicities.

Findings

Threshold enhancement can explain large diphoton signals with minimal new particles.

Charged fermions near half the resonance mass are crucial for the enhancement.

Small total widths are naturally achieved with suppressed three-body decays.

Abstract

The data collected by the LHC collaborations at an energy of 13 TeV indicates the presence of an excess in the diphoton spectrum that would correspond to a resonance of a 750 GeV mass. The apparently large production cross section is nevertheless very difficult to explain in minimal models. We consider the possibility that the resonance is a pseudoscalar boson $A$ with a two--photon decay mediated by a charged and uncolored fermion having a mass at the $\frac12 M_A$ threshold and a very small decay width, $\ll 1$ MeV; one can then generate a large enhancement of the $A\gamma\gamma$ amplitude which explains the excess without invoking a large multiplicity of particles propagating in the loop, large electric charges and/or very strong Yukawa couplings. The implications of such a threshold enhancement are discussed in two explicit scenarios: i) the Minimal Supersymmetric Standard Model in which the $A$ state is produced via the top quark mediated gluon fusion process and decays into photons predominantly through loops of charginos with masses close to $\frac12 M_A$ and ii) a two Higgs doublet model in which $A$ is again produced by gluon fusion but decays into photons through loops of vector--like charged heavy leptons. We also comment on a minimal scenario in which the $A$ state couples only to photons through a heavy lepton loop and is both produced and decays through this coupling. In all these scenarios, while the mass of the charged fermion has to be adjusted to be extremely close to half of the $A$ resonance mass, the small total widths are naturally obtained if only suppressed three-body decay channels occur. Finally, the implications of some of these scenarios for dark matter are discussed.