Exploring the Growth-Index ($γ$) Tension with $Λ_{\rm s}$CDM

Abstract: Recent observational analyses have revealed a significant tension in the growth index $\gamma$, which characterizes the growth rate of cosmic structures. Specifically, when treating $\gamma$ as a free parameter within $\Lambda$CDM framework, a combination of Planck and $ f\sigma_8 $ data yields $\gamma \approx 0.64$, in $\sim4\sigma$ tension with the theoretically expected value $\gamma \approx 0.55$ (assuming general relativity). This discrepancy, closely related to the $ S_8 $ tension, poses a new challenge to the standard cosmological model by suggesting that it predicts an excessive growth of structure. In this work, we demonstrate that the $\Lambda_{\rm s}$CDM framework (featuring a rapid sign-switching cosmological constant (mirror AdS-to-dS transition) in the late universe at redshift $ z_\dagger \sim 2 $) can simultaneously alleviate the $ \gamma $, $ H_0 $, and $ S_8 $ tensions. We also examined a scenario with fixed $ z_\dagger = 1.7 $, previously identified as a sweet spot for alleviating multiple major cosmological tensions (including those in $ H_0 $, $ M_B $, and $ S_8 $) finding that it completely eliminates both the $ \gamma $ and $ H_0 $ tensions, although it is statistically disfavored by our dataset combinations. Our findings suggest that $\Lambda_{\rm s}$CDM is a promising model, providing a potential unified resolution to multiple major cosmological tensions.