Promising interpretation of diphoton resonance at 750 GeV

We study models in which the 750 GeV diphoton excess is due to a scalar decaying to two pseudo-Nambu-Goldstone bosons that subsequently decay into two pairs of highly boosted photons, misidentified as individual photons. Performing a model independent analysis we find that, with axion mass around 200 MeV, this class of theories can naturally explain the observed signal with a large width, without violating monojet constraints. At the same time the requirement of a prompt axion decay can be satisfied only with a relatively large axion-photon coupling, leading to many new charged particles at the TeV scale. However, the required multiplicities of such fields is still moderately reduced relative to models with direct diphoton production.

Section: Introductionmentioning

confidence: 99%

Diphotons from diaxions

Aparicio¹,

Azatov²,

Hardy³

et al. 2016

“…A different approach towards an explanation of the diphoton events is to consider that a single photon in the detector can represent a collimated bunch of photons (typically two of them) which originate from a single very light state, for instance a light pseudoscalar A [5,[30][31][32][33][34][35][36][37]. Then the observed processes correspond to an initial resonance X decaying into a pair A A, where M A must be well below 1 GeV for the resulting photons to be sufficiently collimated (see below).…”

Section: Jhep05(2016)114mentioning

confidence: 99%

“…However, the extrapolation of signal cross sections from 8 to 13 TeV depends on the assumed production mechanism [5][6][7][8][9]. Assuming the production of a resonance around 750 GeV by gluon fusion (ggF), combined fits to the signal cross sections at 13 TeV are in the range 2-10 fb [5][6][7]9], with slightly better fits and a larger signal cross section assuming a larger width of [30][31][32][33][34][35][36][37][38][39][40][41][42][43][44][45] GeV [5,6,9].…”

Section: Introductionmentioning

confidence: 99%

A 750 GeV diphoton signal from a very light pseudoscalar in the NMSSM

Ellwanger

Hugonie

2016

The excess of events in the diphoton final state near 750 GeV observed by ATLAS and CMS can be explained within the NMSSM near the R-symmetry limit. Both scalars beyond the Standard Model Higgs boson have masses near 750 GeV, mix strongly, and share sizeable production cross sections in association with b-quarks as well as branching fractions into a pair of very light pseudoscalars. Pseudoscalars with a mass of ∼ 210 MeV decay into collimated diphotons, whereas pseudoscalars with a mass of ∼ 500-550 MeV can decay either into collimated diphotons or into three π 0 resulting in collimated photon jets. Various such scenarios are discussed; the dominant constraints on the latter scenario originate from bounds on radiative Υ decays, but they allow for a signal cross section up to 6.7 fb times the acceptance for collimated multiphotons to pass as a single photon.

“…In particular, it is important to ask whether light BSM final states may be confused with the diphoton signal. A general framework for such a scenario has been already discussed in several publications [43][44][45][46]. A heavy resonance X produced by the gluon-gluon or quark-antiquark fusion may decay to a pair of light BSM states Y that have weak instability against subsequent decays to electron-positron pairs or photon pairs.…”

Section: Introductionmentioning

confidence: 99%

Diphoton excess through dark mediators

Chen

Lefebvre

Pospelov

et al. 2016

Preliminary ATLAS and CMS results from the first 13 TeV LHC run have encountered an intriguing excess of events in the diphoton channel around the invariant mass of 750 GeV. We investigate a possibility that the current excess is due to a heavy resonance decaying to light metastable states, which in turn give displaced decays to very highly collimated e + e − pairs. Such decays may pass the photon selection criteria, and successfully mimic the diphoton events, especially at low counts. We investigate two classes of such models, characterized by the following underlying production and decay chains: gg → S → A A → (e + e − )(e + e − ) and qq → Z → sa → (e + e − )(e + e − ), where at the first step a heavy scalar, S, or vector, Z , resonances are produced that decay to light metastable vectors, A , or (pseudo-)scalars, s and a. Setting the parameters of the models to explain the existing excess, and taking the ATLAS detector geometry into account, we marginalize over the properties of heavy resonances in order to derive the expected lifetimes and couplings of metastable light resonances. We observe that in the case of A , the suggested range of masses and mixing angles is within reach of several new-generation intensity frontier experiments.