Strongly coupled dark energy cosmologies: preserving ΛCDM success and easing low-scale problems - II. Cosmological simulations

In this second paper, we present the first N-body cosmological simulations of strongly coupled Dark Energy (SCDEW) models, a class of models that alleviates theoretical issues related to the nature of dark energy (DE). SCDEW models assume a strong coupling between DE and an ancillary cold dark matter (CDM) component together with the presence of an uncoupled warm dark matter (WDM) component. The strong coupling between CDM and DE allows us to preserve small-scale fluctuations even if the warm particle is quite light (approximate to 100 eV). Our large-scale simulations show that, for 10(11) < M/M-circle dot < 10(14), SCDEW haloes exhibit a number density and distribution similar to a standard lambda cold dark matter (Lambda CDM) model, even though they have lower concentration parameters. High-resolution simulation of a galactic halo (M similar to 10(12) M-circle dot) shows similar to 60 per cent less substructures than its Lambda CDM counterpart, but the same cuspy density profile. On the scale of galactic satellites (M similar to 10(9) M-circle dot), SCDEW haloes dramatically differ from Lambda CDM. Due to the high thermal velocities of the WDM component they are almost devoid of any substructures and present strongly cored dark matter density profiles. These density cores extend for several hundreds of parsecs, in very good agreement with Milky Way satellites observations. Strongly coupled models, thanks to their ability to match observations on both large and small scales, might represent a valid alternative to a simple Lambda CDM model.