Maps of CMB lensing deflection from N-body simulations in Coupled Dark Energy Cosmologies

TL;DR

This paper creates detailed maps of CMB lensing in different Dark Energy cosmologies using N-body simulations, revealing how DE dynamics influence lensing signals and structure formation.

Contribution

It introduces a method to simulate CMB lensing maps in coupled Dark Energy models, highlighting the impact of DE-CDM interactions on lensing observables and structure growth.

Findings

Standard cDE enhances linear growth and modifies nonlinear structure dynamics.

Bouncing cDE scenario reduces lensing power by 10% compared to LCDM.

Baryons and CDM respond differently to DE coupling, affecting lensing signals.

Abstract

We produce lensing potential and deflection-angle maps in order to simulate CMB weak-lensing via ray-tracing through the COupled Dark Energy Cosmological Simulations (CoDECS). The constructed maps reflect the N-body cosmic structures on a range of scales going from the arcminute to the degree scale. We investigate the variation of the lensing pattern due to the DE dynamics, characterised by different background and perturbation behaviours as a consequence of the interaction between the DE field and CDM. We study the results from three models differing in the background and perturbations evolution, with the purpose to isolate their imprints in the lensing observables. The scenarios investigated include a reference LCDM cosmology, a standard coupled DE (cDE) scenario, and a "bouncing" cDE scenario. For the standard cDE scenario, we find that differences in the lensing potential result from two effects: the enhanced growth of linear CDM density fluctuations with respect to the LCDM case, and the modified nonlinear dynamics of collapsed structures induced by the DE-CDM interaction. As a consequence, CMB lensing highlights the DE impact in the cosmological expansion, even in the degenerate case where the amplitude of the linear matter density perturbations, parametrised through sigma_8, is the same in both the standard cDE and LCDM cosmologies. For the bouncing scenario, we find that the two opposite behaviours of the lens density contrast and of the matter abundance lead to a counter-intuitive effect, making the power of the lensing signal lower by 10% than in the LCDM scenario. Moreover, we compare the behaviour of CDM and baryons in CoDECS separately, in order to isolate effects coming from the coupling with the DE component. We find that, in the bouncing scenario, baryons show an opposite trend with respect to CDM, due to the coupling of the latter with the DE component. [abridged]