Collider signatures of mirror fermions in the framework of Left Right Mirror Model

TL;DR

This paper explores the collider signatures of mirror fermions predicted by a left-right symmetric model with mirror fermions, focusing on their production and detection prospects at the LHC.

Contribution

It introduces a novel left-right mirror model with specific gauge symmetry and discrete symmetry, providing a natural solution to anomaly cancellation and the strong CP problem, and analyzes collider signatures of light mirror fermions.

Findings

Mirror fermions with masses around a few hundred GeV can be produced at the LHC.

The LHC can potentially detect mirror quarks with masses up to approximately 800 GeV.

The model predicts specific resonance signals involving mirror fermions and Z bosons.

Abstract

The idea of left-right symmetry with mirror fermions is very appealing from the symmetry point of view. In this picture, unlike the Standard Model, the symmetry is not only left-right symmetric, but each left handed fermion multiplet is accompanied by new right handed fermion multiplet of opposite chirality. In this work, we consider a gauge symmetry, $SU(3)_c \otimes SU(2)_L\otimes SU(2)_R \otimes U(1)_{Y^\prime}$ supplemented by a discrete $Z_2$ symmetry. Instead of having right handed multiplets for each left handed multiplets of the same fermions as in the usual left-right model, the mirror model include right handed doublets involving new fermions (called mirrors), and similarly for each right handed singlet, there are corresponding mirror singlets. Thus the gauge anomaly is naturally absent in this model, and the model also provide a solution for the strong CP problem because of parity conservation. The first stage of symmetry breaking is achieved by a doublet mirror Higgs with a vacuum expectation value $\simeq 10^7$ GeV, needed to explain the neutrino mass $\simeq 10^{-11}$ GeV. The mirror fermions can mix with the ordinary fermions via a scalar which is singlet under the gauge symmetry. In this model, only light mirror particles, having masses in the few hundred GeV range are $\hat{e}, \hat{u}, \hat{d}$ with well-defined spectrum. $\hat{u}$ and $\hat{d}$ can be pair produced at the LHC, and can be detected as ($u Z$) and ($d Z$) resonances. We discuss the signals of these mirror fermions at the LHC, and find that the reach at the LHC can be as large as $m_{\hat q}\simeq 800$ GeV.