Do equation of state parametrizations of dark energy faithfully capture the dynamics of the late universe?

Abstract

We investigate how strongly late-time inferences about DE dynamics depend on the functional prior used to represent the expansion history. Using identical late-time combinations of CC, DESI BAO measurements, the Pantheon+ SN1a sample, and the H0DN prior, we compare a node-based reconstruction of the reduced Hubble function E(z) with a representative family of smooth low-dimensional DE EoS parametrizations, including CPL. Over the redshift range constrained by the data, both approaches yield consistent H(z), and, in the absence of H0DN, compatible values of H0. However, a clear method dependence emerges at intermediate redshift (z1.7): the reconstruction favors stronger deceleration, q Rec(1.7)0.56-0.61, whereas the smooth parametrizations cluster at q(1.7)0.32-0.40, implying a persistent 2-3σ discrepancy across dataset combinations and parametrizations. For the EoS-based parametrizations, whose effective DE densities remain positive by construction, the preferred w DE(1.7)<-1 values correspond to NECB-violating (phantom-like) behaviour, but this is a less robust discriminator as w DE becomes ill-conditioned as DE0. In the effective-fluid mapping, the reconstruction accommodates the same late-time kinematical preference through a rapid descent of DE(z) toward very small values and a sign change, whereas the EoS-based parametrizations absorb it through smoother, and in several cases NECB-violating, evolution over z1-2. Although the reconstruction improves the best-fit likelihood, especially with H0DN, Bayesian evidence continues to favor the simpler parametric descriptions. Our results isolate z1.5-2 as the key window in which EoS-based DE parametrizations can compress localized kinematic structure and associated features of DE that are still permitted by current late-time data.