Higgs Couplings at the End of 2012

TL;DR

This paper analyzes how well current LHC and Tevatron data constrain the Higgs boson couplings, exploring deviations from the Standard Model and potential new physics contributions.

Contribution

It provides a comprehensive fit of Higgs couplings using latest data, considering both Standard Model and Beyond-the-Standard-Model scenarios, including loop contributions.

Findings

Standard Model fit p-value ~ 0.5

Non-SM contributions improve fit p-value to ~0.9

Sign of top-Higgs coupling opposite to W coupling is disfavored

Abstract

Performing a fit to all publicly available data, we analyze the extent to which the latest results from the LHC and Tevatron constrain the couplings of the Higgs boson-like state at ~ 125 GeV. To this end we assume that only Standard Model (SM) particles appear in the Higgs decays, but tree-level Higgs couplings to the up-quarks, down-quarks and vector bosons, relative to the SM are free parameters. We also assume that the leptonic couplings relative to the SM are the same as for the down-quark, and a custodial symmetry for the V=W,Z couplings. In the simplest approach, the effective Higgs couplings to gluons and photons are computed in terms of the previous parameters. This approach is also applied to Two-Higgs-Doublet Models of Type I and Type II. However, we also explore the possibility that the net Higgs to gluon-gluon and gamma-gamma couplings have extra loop contributions coming from Beyond-the-Standard Model physics. We find that the SM p-value ~ 0.5 is more than 2 sigma away from fits in which: a) there is some non-SM contribution to the gamma-gamma coupling of the Higgs; or b) the sign of the top quark coupling to the Higgs is opposite that of the W coupling. In both these cases p-values ~ 0.9 can be achieved. Since option b) is difficult to realize in realistic models, it would seem that new physics contributions to the effective couplings of the Higgs are preferred.