Effective Lagrangian approach to fermion electric dipole moments induced by a CP--violating $WW\gamma$ vertex

TL;DR

This paper calculates the one-loop contributions of CP-violating $WW\gamma$ vertices to fermion electric dipole moments, updating bounds and analyzing low-energy behavior to understand their physical implications.

Contribution

It provides a detailed analysis of CP-violating $WW\gamma$ couplings' effects on fermion EDMs, updating bounds and clarifying their decoupling behavior at low energies.

Findings

Updated bound on $ ilde{ {kappa}}_\gamma$ to $5.2 imes 10^{-5}$.

Found a less stringent bound on $ ilde{ {lambda}}_\gamma$ of $1.9 imes 10^{-2}$ from neutron EDM.

Estimated EDMs for top and bottom quarks as $10^{-20}$ and $10^{-21} ext{ e} ext{cm}$, respectively.

Abstract

The one--loop contribution of the two CP--violating components of the $WW\gamma$ vertex, $ \tilde{\kappa}_\gamma W^+_\mu W^-_\nu \tilde{F}^{\mu \nu}$ and $(\tilde{\lambda}_\gamma / m^2_W)W^+_{\mu \nu}W^{-\nu}_{\ \rho}\tilde{F}^{\rho \mu}$, on the electric dipole moment (EDM) of fermions is calculated using dimensional regularization and its impact at low energies reexamined in the light of the decoupling theorem. The Ward identities satisfied by these couplings are derived by adopting a $SU_L(2)\times U_Y(1)$--invariant approach and their implications in radiative corrections discussed. Previous results on $\tilde{\kappa}_\gamma$, whose bound is updated to $|\tilde{\kappa}_\gamma| <5.2\times 10^{-5}$, are reproduced, but disagreement with those existing for $\tilde{\lambda}_\gamma$ is found. In particular, the upper bound $|\tilde{\lambda}_\gamma|<1.9\times10^{-2}$ is found from the limit on the neutron EDM, which is more than 2 orders of magnitude less stringent than that of previous results. It is argued that this difference between the $\tilde{\kappa}_\gamma$ and $\tilde{\lambda}_\gamma$ bounds is the one that might be expected in accordance with the decoupling theorem. This argument is reinforced by analyzing careful the low--energy behavior of the loop functions. The upper bounds on the $W$ EDM, $|d_W|<6.2\times 10^{-21} e\cdot cm$, and the magnetic quadrupole moment, $|\tilde{Q}_W|<3\times 10^{-36} e\cdot cm^2$, are derived. The EDM of the second and third families of quarks and charged leptons are estimated. In particular, EDM as large as $ 10^{-20} e\cdot cm$ and $10^{-21} e\cdot cm$ are found for the $t$ and $b$ quarks, respectively.