Litcius/Paper detail

Parametrising non-linear dark energy perturbations

Farbod Hassani, Benjamin L’Huillier, Arman Shafieloo, M. Kunz, Julian Adamek

2020Journal of Cosmology and Astroparticle Physics23 citationsDOIOpen Access PDF

Abstract

In this paper, we quantify the non-linear effects from k-essence dark energy through an effective parameter μ that encodes the additional contribution of a dark energy fluid or a modification of gravity to the Poisson equation. This is a first step toward quantifying non-linear effects of dark energy/modified gravity models in a more general approach. We compare our N-body simulation results from k-evolution with predictions from the linear Boltzmann code \texttt{CLASS}, and we show that for the k-essence model one can safely neglect the difference between the two potentials, Φ −Ψ, and short wave corrections appearing as higher order terms in the Poisson equation, which allows us to use single parameter μ for characterizing this model. We also show that for a large k-essence speed of sound the CLASS results are sufficiently accurate, while for a low speed of sound non-linearities in matter and in the k-essence field are non-negligible. We propose a tanh-based parameterisation for μ, motivated by the results for two cases with low (cs2=10−7) and high (cs2=10−4) speed of sound, to include the non-linear effects based on the simulation results. This parametric form of μ can be used to improve Fisher forecasts or Newtonian N-body simulations for k-essence models.

Topics & Concepts

PhysicsDark energyDark matterSpeed of soundStatistical physicsPoisson distributionEnergy (signal processing)Boltzmann constantTheoretical physicsApplied mathematicsCosmologyClassical mechanicsAstrophysicsQuantum mechanicsStatisticsMathematicsCosmology and Gravitation TheoriesGalaxies: Formation, Evolution, PhenomenaSolar and Space Plasma Dynamics