Evolution of clustering in cosmological models with time-varying dark energy

Abstract

Observations favor cosmological models with a time-varying dark energy component. But how does dynamical dark energy (DDE) influence the growth of structure in an expanding Universe? We investigate this question using high-resolution N-body simulations based on a DDE cosmology constrained by first-year DESI data (DESIY1+DDE), characterized by a 4% lower Hubble constant (H0) and 10% higher matter density (0) than the Planck-2018 model. We examine the impact on the matter power spectrum, halo abundances, clustering, and Baryonic Acoustic Oscillations (BAO). We find that DESIY1+DDE exhibits a 10% excess in power at small scales and a 15% suppression at large scales, driven primarily by its higher 0. This trend is reflected in the halo mass function: DESIY1+DDE predicts up to 70% more massive halos at z = 2 and a 40% excess at z = 0.3. Clustering analysis reveals a 3.71% shift of the BAO peak towards smaller scales in DESIY1+DDE, consistent with its reduced sound horizon compared to Planck18 Measurements of the BAO dilation parameter α, using halo samples with DESI-like tracer number densities across 0 < z < 1.5, agree with the expected DESIY1+DDE-to-Planck18 sound horizon ratio. After accounting for cosmology-dependent distances, the simulation-based observational dilation parameter closely matches DESI Y1 data. We find that the impact of DDE is severely limited by current observational constraints, which strongly favor cosmological models -- whether including DDE or not -- with a tightly constrained parameter 0h2≈ 0.143, within 1-2% uncertainty. Indeed, our results demonstrate that variations in cosmological parameters, particularly 0, have a greater influence on structure formation than the DDE component alone.

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