Abstract
In the Next-to-Minimal Supersymmetric Standard Model (NMSSM), it is possible to have strong mass degeneracies between the new singlet-like scalar and the heavy doublet-like scalar, as well as between the singlet-like and doublet-like pseudoscalar Higgs states. When the difference in the masses of such states is comparable with the sum of their widths, the quantum mechanical interference between their propagators can become significant. We study these effects by taking into account the full Higgs boson propagator matrix in the calculation of the production process of $\tau^+\tau^-$ pairs in gluon fusion at the Large Hadron Collider (LHC). We find that, while these interference effects are sizeable, they are not resolvable in terms of the distributions of differential cross sections, owing to the poor detector resolution of the $\tau^+\tau^-$ invariant mass. They are, however, identifiable via the inclusive cross sections, which are subject to significant variations with respect to the standard approaches, wherein the propagating Higgs bosons are treated independently from one another. We quantify these effects for several representative benchmark points, extracted from a large set of points, obtained by numerical scanning of the NMSSM parameter space, that satisfy the most important experimental constraints currently available.
Highlights
Supersymmetry (SUSY) predicts the existence of at least two Higgs doublets of opposite hypercharge, which are necessary to cancel chiral anomalies, unlike the standard model (SM), where only one Higgs doublet is sufficient
Among the ones passing all the constraints, we identify a few benchmark points (BPs) and carry out the cross section comparison noted above for them, using a Monte Carlo (MC) integration code developed in house
We have considered the specific example of the next-to-minimal supersymmetric standard model (NMSSM), wherein nearly identical-mass pairs of CP-even or CP-odd Higgs bosons are viable over substantial regions of the parameter space
Summary
Supersymmetry (SUSY) predicts the existence of at least two Higgs doublets of opposite hypercharge, which are necessary to cancel chiral anomalies, unlike the standard model (SM), where only one Higgs doublet is sufficient. We quantify the impact of quantum interference on the process where nearly mass-degenerate heavy Higgs bosons are produced in gluon fusion at the 14 TeV LHC and decay into τþτ− pairs. This is done by comparing the cross section obtained by including the full Higgs propagator matrix in the expression for amplitude and the one obtained by assuming two (or more) individual Breit-Wigner (BW) Higgs propagators with nearly identical poles.
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