The precision electroweak data in warped extra-dimension models

The Randall-Sundrum scenario with Standard Model fields in the bulk and a custodial symmetry is considered. We determine the several minimal quark representations allowing to address the anomalies in the forward-backward b-quark asymmetry AFBb, while reproducing the bottom and top masses via wave function overlaps. The calculated corrections of the Zb¯b coupling include the combined effects of mixings with both Kaluza-Klein excitations of gauge bosons and new b′-like states. It is shown that the mechanism, in which the left-handed doublet of third generation quarks results from a mixing on the UV boundary of introduced fields Q1L and Q2L, is necessary for phenomenological reasons. Within the obtained models, both the global fit of Rb with AFBb [at the various center of mass energies] and the fit of last precision electroweak data in the light fermion sector can simultaneously be improved significantly with respect to the pure Standard Model case, for MKK=3, 4, 5 TeV (first KK gauge boson) and a best-fit Higgs mass mh⩾115 GeV i.e. compatible with the LEP2 direct limit. The quantitative analysis of the oblique parameters S,T,U even shows that heavy Higgs mass values up to ∼500 GeV may still give rise to an acceptable quality of the electroweak data fit, in contrast with the Standard Model. The set of obtained constraints on the parameter space, derived partly from precision electroweak data, is complementary of a future direct exploration of this parameter space at the LHC. In particular, we find that custodians, like b′ modes, can be as light as ∼1200GeV i.e. a mass lying possibly in the potential reach of LHC.