Multi-photon decays of the Higgs boson at the LHC

Abstract

Many new physics scenarios predict multi-photon Higgs resonances. One such scenario is the dark axion portal model. The primary decay chain that we study is the Higgs to dark photon (γD) pairs that subsequently decay into a photon (γ) and an axion-like particle (a). The axion-like particles then decay into photon pairs. Hence, the signal is a six-photon Higgs decay: h→ γD\,γD→ 2\,γ 2\,a→ 6γ. However, depending on the relevant kinematics, the photons can become well-collimated and appear as photon-jets (multiple photons that appear as a single photon in the detector) or -jets (non-isolated multi-photon signals that do not pass the isolation criterion). These effects cause the true six-photon resonance to appear as other multi-photon signals, such as two and four photons. We classify the mass regions where two, four, and six-photon resonances dominate. The four-photon signal is particularly interesting. These events mainly occur when the photons from the axion-like particles are collimated into photon-jets. The decay of the dark photon is then γD→ γ a→ γ+γ-jet, which is an apparent violation of the Landau-Yang theorem. We show that current measurements of h→ 2γ and searches for h→ 4γ at the Large Hadron Collider (LHC) can limit BR(h→ γDγD) 10-3. This model also motivates new searches for Higgs decays into six isolated photons or -jets at the LHC. While there are currently no dedicated searches, we show that many of the Higgs to six isolated photons or -jet events could pass two or three-photon triggers. That is, new physics could be found by reanalyzing existing data. These multi-photon signals provide excellent footing to explore new physics at the LHC and beyond.