Abstract

We investigate the minimal $U(1)_{L_\mu-L_\tau}$ model with extra heavy vector-like leptons or charged scalars. By studying the kinetic mixing between $U(1)_{L_\mu-L_\tau}$ gauge boson $Z^\prime$ and standard model photon, which is absent at tree level and will arise at one loop level due to $\mu$, $\tau$ and new heavy charged leptons or scalars, the interesting behavior is shown. It can provide possibility for visible signatures of new heavy particles. We propose to search for $Z^\prime$ at electron collider experiments, such as Belle II, BESIII and future Super Tau Charm Factory (STCF), using the monophoton final state. The parameter space of $Z^\prime$ is probed, and scanned by its gauge coupling constant $g_{Z^\prime}$ and mass $m_{Z^\prime}$. We find that electron colliders have sensitivity to the previously unexplored parameter space for $Z^\prime$ with MeV-GeV mass. Future STCF experiments with $\sqrt s=2-7$ GeV can exclude the anomalous muon magnetic moment favored area when $m_{Z^\prime}<5$ GeV with the luminosity of 30 ab$^{-1}$. For $m_{Z^\prime} < 2m_\mu$, $g_{Z^\prime}$ can be down to $4.2\times 10^{-5}$ at 2 GeV STCF.

Highlights

  • The standard model (SM) of particle physics is a successful and highly predictive theory of fundamental particles and interactions but fails to explain many phenomena, including neutrino mass, baryon asymmetry of the Universe, and the presence of dark matter and dark energy, among others

  • We propose to search for Z0 at electron collider experiments, such as Belle II, BESIII, and future Super Tau Charm Factory (STCF), using the monophoton final state

  • We find that electron colliders have sensitivity to the ppreffiffiviously unexplored parameter space for Z0 with MeV–GeV mass

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Summary

INTRODUCTION

The standard model (SM) of particle physics is a successful and highly predictive theory of fundamental particles and interactions but fails to explain many phenomena, including neutrino mass, baryon asymmetry of the Universe, and the presence of dark matter and dark energy, among others. The Uð1ÞLμ−Lτ model [1,2,3], with a Uð1ÞLμ−Lτ extension of SM, gauges the difference of the leptonic muon and tau number and induces a new vector boson Z0. We investigate the γ − Z0 kinetic mixing in the minimal Uð1ÞLμ−Lτ with extra heavy vectorlike leptons or charged scalars. STCF is a proposed symmetric detector experiment which collides electron with a positron in the range of center-of-mass energies from 2.0 to 7.0 GeV with the peak luminosity Oð1035Þ cm−2 s−1 at 4 GeV [38,39,40]. Though the additional leptons and scalars cannot be detected directly due to their heavy mass, they can provide significant contributions to the kinetic mixing

Decay modes of Z0
EXISTING CONSTRAINTS
BELLE II
BESIII AND STCF
RESULTS
VIII. SUMMARY

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