$W$-Boson Mass, Electroweak Precision Tests and SMEFT

JiJi Fan, Lingfeng Li, Tao Liu, Kun-Feng Lyu

Published 2022-04-11Version 1

Recently the CDF collaboration at the Tevatron reported a significant discrepancy between the direct measurement of the $W$-boson mass and its Standard Model (SM) prediction based on electroweak precision tests (EWPTs). In this paper we explore the potential origin of this discrepancy from physics beyond the SM. Explicitly, we work on a set of six-dimensional operators in the SM effective field theory which are relevant to the EWPTs. By fitting to the data, we demonstrate that an upward shift in $m_W$ is driven by the operator $\mathcal{O}_{T}=\frac{1}{2}(H^{\dagger}\overset{\text{$\leftrightarrow$}}{D}_{\mu}H)^2$ with a coefficient $c_T ({\rm TeV}/\Lambda)^2 \gtrsim 0.01$. This suggests that the new physics scale favored by the CDF data could be within the reach of current and near-future LHC searches. We also comment on other further indirect tests of the physical origin for this anomalous discrepancy such as the Higgs couplings.