Abstract We investigate linear matter density perturbations in the Λ s CDM scenario, in which the Λ is replaced by one that undergoes a late-time ( z ∼ 2) mirror AdS-dS transition, resulting in distinct growth dynamics that shape cosmic structure evolution. We begin our analysis by developing a systematic method to track perturbation growth using two complementary approaches: (i) determining the initial density contrast and its evolution rate for a given collapse scale factor, and (ii) computing the collapse scale factor for a specified initial density contrast and evolution rate. We derive analytical solutions for the growth rate f = Ω m γ and growth index γ in both models, reinforcing the theoretical foundation of our approach. Our analysis indicates that prior to the transition, during the AdS-like phase — the AdS-like Λ in Λ s CDM reduces cosmic friction, causing linear matter density perturbations to grow more rapidly than in ΛCDM; this effect is most pronounced just before the transition, with a growth rate approximately 15% higher than that of ΛCDM around z ∼ 2. After the transition, Λ s CDM behaves similarly to ΛCDM but features a larger cosmological constant, leading to higher H ( z ) and greater cosmic friction that more effectively suppresses growth. Before the transition, the growth index γ remains below both the ΛCDM and Einstein-de Sitter values (γ ≈ 6/11); during the transition, it increases rapidly and then grows gradually, paralleling ΛCDM while remaining slightly higher in the post-transition era-though overall, it stays near γ ∼ 0.55, as in the ΛCDM model. Using the Planck best-fit values, namely Ω m0 = 0.28 for Λ s CDM and Ω m0 = 0.32 for ΛCDM, we find that the corresponding growth rates at z = 0 are f = 0.49 and f = 0.53, respectively. Notably, Λ s CDM predicts a value closer to f = 0.48, recently obtained from LSS data when γ is treated as a free parameter in ΛCDM. This suggests that Λ s CDM may naturally resolve the structure growth anomaly, without deviating from γ ∼ 0.55. The analysis of linear matter perturbations underscores Λ s CDM's potential to resolve multiple cosmological tensions within a unified framework, motivating further exploration of its implications for nonlinear structure formation and observational tests.
Akarsu et al. (Fri,) studied this question.
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