Dynamical Dark Energy in the Crosshairs: A Joint Analysis with DESI, Pantheon plus, and TDCOSMO Constraints
Abstract
The cosmological tensions between early- and late-Universe probes, particularly the Hubble tension ($H_0$) and $S_8$ discrepancy, challenge the validity of the standard ${\rm{\Lambda}CDM}$ model. Motivated by these tensions, we perform a comprehensive joint analysis of three representative dark energy models - ${\rm{\Lambda}CDM}$, the Chevallier-Polarski-Linder (CPL) parametrization, and the Phenomenologically Emergent Dark Energy (PEDE) model - using the latest observational datasets: baryon acoustic oscillation (BAO) measurements from DESI Data Releases 1 and 2 (DR1/DR2), the Pantheon Plus sample of Type Ia supernovae (SNe Ia), and time-delay cosmography from TDCOSMO lensing. Our multi-probe approach breaks key degeneracies among cosmological parameters ($H_0$, $r_d$, and $M_B$) and provides robust constraints on dark energy dynamics. The CPL model yields a statistically significant improvement over ${\rm{\Lambda}CDM}$, with $\Delta \chi^2 \approx -3.6$ for DESI DR2+Pantheon Plus+TDCOSMO, favoring a quintessence-like behavior ($w_0=-0.87^{+0.045 }_{-0.045} $, $w_a=-0.41^{+ 0.28}_{-0.28}$ at 1$\sigma$ confidence level). In contrast, the PEDE model exhibits severe tension with observations, yielding $\Delta \chi^2 \approx +53.1$ (DR1) and $\Delta \chi^2 \approx +132.3$ (DR2), despite its potential to marginally alleviate the $H_0$ tension. DESI DR2 tightens constraints on dynamical dark energy by $\sim$40\%, reinforcing evidence for redshift-evolving $w(z)$. Remarkably, our results demonstrate that such data combination can achieve precision comparable to Planck CMB measurements for dynamical dark energy studies, while offering complementary advantages in probing the late-time universe. This synergy between different observational data significantly enhances our ability to constrain dark energy properties.