Abstract
We present a case study for the doubly charged Higgs boson pair production in and pp colliders with their subsequent decays to four charged leptons. We consider the Higgs Triplet Model ( ), which is not restricted by the custodial symmetry, and the Minimal Left-Right Symmetric Model ( ). These models include scalar triplets with different complexities of scalar potentials and, because of experimental restrictions, completely different scales of non-standard triplet vacuum expectation values. In both models, a doubly charged Higgs boson can acquire a mass of hundreds of gigaelectronvolts, which can be probed at the HL-LHC, future , and hadron colliders. We take into account a comprehensive set of constraints on the parameters of both models coming from neutrino oscillations, LHC, , and low-energy lepton flavor violating data and assume the same mass of . Our finding is that the pair production in lepton and hadron colliders is comparable in both models, though more pronounced in the . We show that the decay branching ratios can be different within both models, leading to distinguishable four-lepton signals, and that the strongest are events yielded by the . Typically, we find that the signals are one order of magnitude larger those in the . For example, the signal for 1 TeV mass results in a clearly detectable significance of for the HL-LHC and for the FCC-hh. Finally, we provide quantitative predictions for the dilepton invariant mass distributions and lepton separations, which help to identify non-standard signals.
Highlights
Numerical results for s = 1.5 TeV are gathered in Fig. 7 and Fig. 8 for the Higgs Triplet Model (HTM) and Minimal Left-Right Symmetric Model (MLRSM), respectively
The doubly charged Higgs boson H±± pair production at e+e− and pp colliders, with their subsequent decays to four charged leptons, can provide a very clear signal when searching for non-standard scalar particle effects without missing energy
We discuss a relation between the vacuum expectation value of the triplet v∆ and H±± couplings with leptons, taking into account constraints on v∆ coming from low energy studies connected with the ρ-parameter, muon (g − 2)μ, lepton flavor violation, e+e−, LHC processes, and neutrino oscillations
Summary
The spectacular discovery of the chargeless Higgs particle (H0) at the LHC [1,2,3] is consistent with the prediction of the Standard Model (SM), confirming the basic concept of the spontaneous symmetry breaking mechanism and elementary particle mass generation. The mass suppressed decay rate to muon pairs when compared with top pairs is evident [12, 16]. Another spectacular success of the LHC physics is the clear discovery that the Higgs boson decays to the third generation of fermions, namely to the pairs of τ leptons and b-quarks.
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