Nonlinear Matter Power Spectrum from relativistic N-body Simulations: sCDM versus
Abstract
We present relativistic N-body simulations of a sCDM - sign-switching cosmological constant (CC) - scenario under general relativity and compare its nonlinear matter power spectrum to at z = 15,\,2,\,1,\,0, using best-fit parameters from Planck-only and a combined ''full'' dataset. During the AdS-like CC ( s<0) phase, prior to the transition redshift z, reduced Hubble friction dynamically enhances the growth of perturbations; after the switch, with dS-like CC ( s>0), the larger late-time expansion rate partly suppresses, but does not erase, the earlier amplification. Consequently, the ratio P_ s CDM/P CDM exhibits a pronounced, redshift-dependent shape feature: a crest peaking at 20-25\% around k 1-3\,h\,Mpc-1 near the transition, which then migrates to larger physical scales and persists to z = 0 as a robust 15-20\% uplift at k 0.6-1.0\,h\,Mpc-1. These wavenumbers correspond to group or poor-cluster environments and lie within the sensitivity range of weak lensing, galaxy-galaxy lensing, cluster counts, and tSZ power, providing a concrete, falsifiable target that cannot be mimicked by a scale-independent change in σ8 or S8. The timing (earlier for Planck-only, later for the full dataset) and the amplitude of the crest align with the ''cosmic noon'' epoch (z 1-2), offering a gravitational prior for the observed peak in the cosmic star-formation rate.
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