Generalized Emergent Dark Energy: observational Hubble data constraints and stability analysis

Abstract

Recently PEDE:2019ApJ proposed a phenomenologically emergent dark energy (PEDE) which consider that the dark energy density evolves as DE(z)\,=\,DE,0[ 1 - tanh( 10(1+z) ) ] with the advantage that it does not have degree of freedom. Later on, PEDE:2020 proposed a generalized model by adding one degree of freedom to the PEDE model, encoded in the parameter . Motivated by these proposals, we constrain the parameter space (h,m) and (h,m, ) for PEDE and Generalized Emergent Dark Energy (GEDE) respectively, by employing the most recent observational (non-) homogeneous Hubble data. Additionally, we reconstruct the deceleration and jerk parameters and estimate yield values at z=0 of q0 = -0.784+0.028-0.027 and j0 = 1.241+0.164-0.149 for PEDE and q0 = -0.730+0.059-0.067 and j0 = 1.293+0.194-0.187 for GEDE using the homogeneous sample. We report values on the deceleration-acceleration transition redshift with those reported in the literature within 2σ CL. Furthermore, we perform a stability analysis of the PEDE and GEDE models to study the global evolution of the Universe around their critical points. Although the PEDE and GEDE dynamics are similar to the standard model, our stability analysis indicates that in both models there is an accelerated phase at early epochs of the Universe.