We perform a complete calculation at the one-loop level for the Zggg and Zggg couplings in the context of the minimal 331 model, which predicts the existence of a new Z gauge boson and new exotic quarks. Bose symmetry is exploited to write a compact
and manifest SU_C(3)-invariant vertex function for the Vggg (V=Z,Z) coupling. Previous results on the $Zto ggg$ decay in the standard model are reproduced. It is found that this decay is insensitive to the effects of the new exotic quarks. This in contrast with the $Zto ggg$ decay, which is sensitive to both the standard model and exotic quarks, whose branching ratio is larger than that of the $Zto ggg$ transition by about a factor of 4.
Higgs mediated flavor violating electromagnetic interactions, induced at the one--loop level by a nondiagonal $Hf_if_j$ vertex, with $f_i$ and $f_j$ charged leptons or quarks, are studied within the context of a completely general effective Yukawa se
ctor that comprises $SU_L(2)times U_Y(1)$--invariant operators of up to dimension--six. Exact formulae for the one--loop $gamma f_if_j$ and $gamma gamma f_if_j$ couplings are presented and their related processes used to study the phenomena of Higgs mediated lepton flavor violation. The experimental limit on the $mu to egamma$ decay is used to derive a bound on the branching ratio of the $mu to egamma gamma$ transition, which is 6 orders of magnitude stronger than the current experimental limit. Previous results on the $tau to mu gamma$ and $tau to mu gamma gamma$ decays are reproduced. The possibility of detecting signals of lepton flavor violation at $gamma gamma$ colliders is explored through the $gamma gamma to l_il_j$ reaction, putting special emphasis on the $tau mu$ final state. Using the bound imposed on the $Htau mu$ vertex by the current experimental data on the muon anomalous magnetic moment, it is found that about half a hundred events may be produced in the International Linear Collider.
The tau -> (omega, phi)P^- u decays, where P^-=pi^-, K^-, are considered within a phenomenological model with dominance of meson intermediate states. We assume SU(3) flavor symmetry to fix some of the unknown strong interaction couplings. Our predict
ions for the tau -> phi (pi^-, K^-) u branching fractions are in good agreement with recent measurements of the BABAR and BELLE Collaborations.
