Measuring the electron Yukawa coupling via resonant s-channel Higgs production at FCC-ee

Abstract

The Future Circular Collider (FCC-ee) offers the unique opportunity of studying the Higgs coupling to the electron, ye, via resonant s-channel production, e+e- H, in a dedicated run at s = mH. The signature for direct Higgs production is a small rise in cross sections for particular final states, consistent with Higgs decays, over the expectations for their occurrence due to SM background processes involving Z*,γ*, or t-channel exchanges. Performing such a measurement is remarkably challenging for four main reasons. First, the low value of the e mass leads to a tiny ye coupling, and correspondingly small cross section: σee H\, me2 = 0.57 fb accounting for initial-state radiation. Second, the e+e- beams must be monochromatized such that their c.m. energy spread is commensurate with the narrow width of the SM Higgs boson, H = 4.1 MeV, while keeping large beam luminosities. Third, the Higgs mass must also be known beforehand with a few-MeV accuracy in order to operate the collider at the resonance peak, s = mH. Last but not least, the cross sections of the background processes are many orders-of-magnitude larger than those of the Higgs decay signals. A generator-level study of 11 Higgs decays using a multivariate analysis, exploiting BDTs to discriminate signal and background events, identifies two final states as the most promising ones in terms of statistical significance: H gg and H WW* + 2 jets. For a benchmark 4.1-MeV c.m. energy spread (leading to σee H\, = 0.28 fb) and Lint=10 ab-1, a 1.3σ signal significance can be reached, corresponding to an upper limit on the e Yukawa at 1.6 times the SM value: |ye|<1.6|ySMe| at 95\% confidence level, per IP per year. Directions for future improvements of the study are outlined.