A General Analysis of Wtb anomalous Couplings

Abstract

We investigate new physics effects on the Wtb effective couplings in a model-independent manner. The new physics effects are summarized as four independent couplings f1L, f1R, f2L and f2R. Using single-top-quark productions and W-helicity fraction measurements at the LHC and Tevatron, we perform a global fit to impose constraints on top quark effective couplings. We introduce a set of parameters x0, xm, xp and x5 to study the correlations among Wtb effective couplings. We show that (i) improving the measurements of σt and σtW is important in constraining the correlation of (f1R,f2R) and (f2L,f2R); (ii) f1L and f2R are anti-correlated, which is sensitive to all the experiments; (iii) f1R and f2L are also anti-correlated, which is sensitive to the W-helicity measurements; (iv) the correlation between f2L and f2R is sensitive to the precision of σt, σtW and F0 measurements. The effective Wtb couplings are studied in three kinds of new physics models: SU(2)1 × SU(2)2 × U(1)X models, vector-like quark models and Littlest Higgs model with and without T-parity. The Wtb couplings in the left-right model and the un-unified model are sensitive to the ratio of gauge couplings when the new heavy gauge boson's mass (MW') is less than several hundred GeV, but the constraint is loose if MW'>1 TeV. The Wtb couplings in vector-like quark models and the Littlest Higgs models are sensitive to the mixing angles of new heavy particles and SM particles. We also include the constraints of the oblique T-parameter and Zbb couplings which impose much tighter constraints on the mixing angles. We show that the Wtb coupling constraints become relevant if the precision of single top production cross section measurements could be reduced to 1\% relative to the SM predictions in future.