Revealing the $q^2$ dependence in $b \to s \mu^+ \mu^-$ baryonic decay modes

TL;DR

This paper analyzes the $q^2$ dependence in baryonic $b o s \, \mu^+ \mu^-$ decays, comparing Standard Model predictions with six new physics scenarios to identify potential deviations and effects.

Contribution

It provides a model-independent analysis of baryonic decay modes, exploring various new physics scenarios and their impact on observables like branching ratios and angular distributions.

Findings

Certain new physics scenarios significantly alter decay observables.

Predictions for angular observables and branching ratios are provided.

Discrepancies with Standard Model predictions are identified in specific decay channels.

Abstract

Measurements from the LHCb experiment and $B$ factories have revealed several discrepancies in angular observables of rare semileptonic $B$ decays involving the quark-level transition $b \to s \ell^+ \ell^-$. In this work, we conduct a model-independent comparative analysis of the rare semileptonic decays of baryons $\Lambda_b$, $\Sigma_b$ and $\Xi_b$, exploring various new physics scenarios. Our analysis includes predictions for branching ratios and angular observables, including forward-backward asymmetry, longitudinal polarization fractions, and lepton flavor universality ratios, both within the Standard Model and across six distinct new physics scenarios. Notably, we find that certain new physics scenarios significantly affect the observables in the $(\Lambda_b, \Sigma_b, \Xi_b) \to (\Lambda, \Sigma, \Xi) \mu^+ \mu^-$ processes.