Phenomenological anatomy of top-quark FCNCs induced by a light scalar singlet

Abstract

Scalar singlets under the Standard Model gauge group appear naturally in many well-motivated New Physics scenarios, such as the composite Higgs models. Unlike the Higgs boson in the Standard Model, they can induce large flavour-changing neutral currents (FCNCs) in the top sector. We investigate systematically the effects of a light scalar singlet S with top-quark FCNC couplings, by including the low-energy constraints from the Bs μ+ μ- decay, the muon anomalous magnetic moment (g-2)μ and the neutron Electric Dipole Moment (EDM). We also perform a detailed Monte-Carlo simulation of the channel pp t S +j with S μ+ μ- and S b b, and investigate the LHC sensitivity to the tcS couplings. It is found that the scalar singlet S can induce scalar-type contributions to the Bs μ+ μ- decay, which do not suffer from the helicity suppression and contain a large CKM factor Vcs*Vtb. As a result, constraints on the tcS couplings from the measured branching ratio B(Bs μ+ μ-) are quite stringent, being even stronger than the expected LHC sensitivity in some parameter spaces. Besides the CP-conserving tcS couplings, we have also considered the case of CP-violating tcS couplings, with yR,Lct=|yR,Lct|eiθR,L. It is found that the CP observables A_sμμ and Sμμ of the Bs μ+ μ- decay are sensitive to the phase θR, while the neutron EDM can provide bounds on the phase difference θL-θR. Therefore, they are complementary to each other in probing the CP phases of the tcS couplings.