Dark energy with a gradient coupling to the dark matter fluid: cosmological dynamics and structure formation

TL;DR

This paper explores a covariant scalar field model of dark energy interacting with dark matter, analyzing its cosmological dynamics and structure formation effects, revealing potential deviations from standard cosmology.

Contribution

It introduces a novel covariant framework for dark energy-dark matter interaction using Scalar-Fluid theories, with comprehensive background and perturbation analyses.

Findings

Late-time transitions from dark matter to dark energy domination

Existence of matter and accelerated scaling solutions

Potential observational signatures in structure formation

Abstract

We consider scalar field models of dark energy interacting with dark matter through a coupling proportional to the contraction of the four-derivative of the scalar field with the four-velocity of the dark matter fluid. The coupling is realized at the Lagrangian level employing the formalism of Scalar-Fluid theories, which use a consistent Lagrangian approach for relativistic fluid to describe dark matter. This framework produces fully covariant field equations, from which we can derive unequivocal cosmological equations at both background and linear perturbations levels. The background evolution is analyzed in detail applying dynamical systems techniques, which allow us to find the complete asymptotic behavior of the universe given any set of model parameters and initial conditions. Furthermore we study linear cosmological perturbations investigating the growth of cosmic structures within the quasi-static approximation. We find that these interacting dark energy models give rise to interesting phenomenological dynamics, including late-time transitions from dark matter to dark energy domination, matter and accelerated scaling solutions and dynamical crossing of the phantom barrier. Moreover we obtain possible deviations from standard $\Lambda$CDM behavior at the linear perturbations level, which have an impact on the dynamics of structure formation and might provide characteristic observational signatures.