LHC and dark matter implications of t-b-{\tau} Yukawa unification in split SUSY GUTs

TL;DR

This paper explores a grand unification inspired split supersymmetry model with Yukawa unification, analyzing its compatibility with current collider and dark matter experimental constraints, and identifying viable parameter regions.

Contribution

It introduces a GUT-inspired split SUSY model with Yukawa unification, analyzing its phenomenology under current experimental constraints using numerical scans.

Findings

Viable parameter regions consistent with Yukawa unification and Higgs mass.

Current experimental bounds significantly constrain the model.

Some parameter space remains testable in future experiments.

Abstract

We investigate a grand unification (GUT) inspired version of the minimal supersymmetric standard model (MSSM) based on a left-right symmetric $4$-$2$-$2$ gauge group, incorporating Yukawa coupling unification and current phenomenological constraints. Utilizing a split soft supersymmetry-breaking (SSB) parameter space motivated by flavor symmetries, we analyze the implications of recent results from ATLAS, CMS, LHCb, and dark matter direct detection experiments. Our numerical scans, conducted with SARAH and SPheno, identify viable low-energy regions consistent with third-generation Yukawa unification, the observed Higgs boson mass, dark matter relic density, and flavor observables such as $B \to X_s \gamma$, $B_s \to \mu^+ \mu^-$ and $B_u \to \tau \nu_{\tau}$ . Our findings suggest that while current bounds severely constrain much of the MSSM-like parameter space, substantial regions remain experimentally viable and testable in the ongoing LHC run and next-generation dark matter experiments.