Abstract
We investigate the prospects of discovering the top quark decay into a charm quark and a Higgs boson ($t \to c h^0$) in top quark pair production at the CERN Large Hadron Collider (LHC). A general two Higgs doublet model is adopted to study flavor changing neutral Higgs (FCNH) interactions. We perform a parton level analysis as well as Monte Carlo simulations using \textsc{Pythia}~8 and \textsc{Delphes} to study the flavor changing top quark decay $t \to c h^0$, followed by the Higgs decaying into $\tau^+ \tau^-$, with the other top quark decaying to a bottom quark ($b$) and two light jets ($t\to bW\to bjj$). To reduce the physics background to the Higgs signal, only the leptonic decays of tau leptons are used, $\tau^+\tau^- \to e^\pm\mu^\mp +\slashed{E}_T$, where $\slashed{E}_T$ represents the missing transverse energy from the neutrinos. In order to reconstruct the Higgs boson and top quark masses as well as to effectively remove the physics background, the collinear approximation for the highly boosted tau decays is employed. Our analysis suggests that a high energy LHC at $\sqrt{s} = 27$ TeV will be able to discover this FCNH signal with an integrated luminosity $\mathcal{L} = 3$ ab$^{-1}$ for a branching fraction ${\cal B}(t \to ch^0) \agt 1.4 \times 10^{-4}$ that corresponds to a FCNH coupling $|\lambda_{tch}| \agt 0.023$. This FCNH coupling is significantly below the current ATLAS combined upper limit of $|\lambda_{tch}| = 0.064$.
Highlights
The discovery of the Higgs boson in 2012 [1,2] completed the experimental observation of the particle spectrum predicted by the Standard Model (SM)
We investigate the discovery potential of the top-quark decay into a charm quark and a Higgs boson (t → ch0) followed by the Higgs boson decaying into τþτ− in top-quark pair production at the CERN Large Hadron Collider (LHC)
We focus on the discovery channel with one top quark decaying hadronically (t → bjj), while the other top quark decays into a charm quark and a Higgs boson (h0) followed by h0 → τþτ− → eÆμ∓ þ =ET
Summary
The discovery of the Higgs boson in 2012 [1,2] completed the experimental observation of the particle spectrum predicted by the Standard Model (SM). This leads to an upper limit on the FCNH Yukawa coupling jλtchj λtch ≤ 0.064. To investigate the discovery potential of a flavorchanging neutral Higgs boson signal with low physics background, we consider only the leptonic decays of the tau leptons, τþτ− → eÆμ∓ þ =ET, where =ET is the missing transverse energy in the event from the neutrinos This is complementary to the ATLAS searches for same-charge dileptons
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