The flavor of a light charged Higgs

TL;DR

This paper investigates the potential explanation of a 3σ excess observed by ATLAS for a light-charged Higgs in top decays, proposing a three-Higgs doublet model with specific Yukawa coupling enhancements.

Contribution

It introduces a three-Higgs doublet model that can explain the ATLAS excess, contrasting with other models that cannot account for the signal, and discusses testable Yukawa coupling scenarios.

Findings

A three-Higgs doublet model can explain the excess.

Yukawa couplings of the neutral pseudoscalar need to be enhanced.

Two minimal scenarios for Yukawa couplings are proposed.

Abstract

The ATLAS Collaboration has recently reported a search for light-charged Higgs in $t\to H^+ b$ decay, with $H^+\to c\bar b$. An excess with a local significance of approximately $3\sigma$ is found at $m_{H^+}\approx130$ GeV, with a best-fit value of ${\rm BR}(t\to H^+b)\times {\rm BR}(H^+\to c\bar b)=(1.6\pm0.6)\times10^{-3}$. We study the implications of such a hypothetical signal in multi-Higgs doublet models. We take into account constraints from searches for other charged Higgs decays and from flavor-changing neutral current processes. Two Higgs doublet models with flavor structure dictated by natural flavor conservation (NFC), minimal flavor violation (MFV), or the Froggatt-Nielsen (FN) mechanism cannot account for such excess. A three-Higgs doublet model with NFC can account for the signal. The Yukawa couplings of the neutral pseudoscalar $A$ in the down sector, $\hat Y_A^D$, should be larger by a factor of $4-6$ compared to the corresponding Yukawa couplings of the Higgs $h$, $\hat Y_h^D$. We further present two minimal scenarios, one in which a single Yukawa coupling in the down sector, $(\hat Y_A^D)_{bb}$, gives the only significant contribution, and one in which two Yukawa couplings in the up sector, $(\hat Y_A^U)_{tt}$ and $(\hat Y_A^U)_{tc}$, give the only significant contributions, and we discuss possible tests of these scenarios.