Incorporating doubly resonant $W^\pm$ data in a global fit of SMEFT parameters to lift flat directions

TL;DR

This paper enhances SMEFT parameter constraints by incorporating doubly resonant W boson data, resolving degeneracies, and emphasizing the importance of consistent theoretical and observational treatment in global fits.

Contribution

It introduces a calculation of double pole contributions in SMEFT, updates global fits with charged current data, and discusses the impact on Wilson coefficient constraints and degeneracy resolution.

Findings

Charged current data lifts previous degeneracies in SMEFT fits.

Constraints on 20 of 53 Wilson coefficients are obtained.

Inclusion of theoretical errors and consistent observables treatment is crucial.

Abstract

We calculate the double pole contribution to two to four fermion scattering through $W^{\pm}$ currents at tree level in the Standard Model Effective Field Theory (SMEFT). We assume all fermions to be massless, $\rm U(3)^5$ flavour and $\rm CP$ symmetry. Using this result, we update the global constraint picture on SMEFT parameters including LEPII data on these charged current processes, and also include modifications to our fit procedure motivated by a companion paper focused on $W^{\pm}$ mass extractions. The fit reported is now to 177 observables and emphasises the need for a consistent inclusion of theoretical errors, and a consistent treatment of observables. Including charged current data lifts the two-fold degeneracy previously encountered in LEP (and lower energy) data, and allows us to set simultaneous constraints on 20 of 53 Wilson coefficients in the SMEFT, consistent with our assumptions. This allows the model independent inclusion of LEP data in SMEFT studies at LHC, which are projected into the SMEFT in a consistent fashion. We show how stronger constraints can be obtained by using some combinations of Wilson coefficients, when making assumptions on the UV completion of the Standard Model, or in an inconsistent analysis. We explain why strong bounds at the per-mille or sub-per-mille level on some combinations of Wilson coefficients in the Effective Lagrangian can be artificially enhanced in fits of this form in detail. This explains some of the different claims present in the literature.