Addressing the DESI DR2 Phantom-Crossing Anomaly and Enhanced H0 Tension with Reconstructed Scalar-Tensor Gravity

Abstract

Recent cosmological data, including DESI DR2, highlight significant tensions within the ΛCDM paradigm. When analyzed in the context of General Relativity (GR), the latest DESI data favor a dynamical dark energy (DDE) equation of state, w(z), that crosses the phantom divide line w=-1. However, this framework prefers a lower Hubble constant, H0, than Planck 2018, thereby worsening the tension with local measurements. This phantom crossing is a key feature that cannot be achieved by minimally coupled scalar fields (quintessence) within GR. This suggests the need for a new degree of freedom that can simultaneously: (A) increase the best-fit value of H0 in the context of the DESI DR2 data, and (B) allow the crossing of the w=-1 line within a new theoretical approach. We argue that both of these goals may be achieved in the context of Modified Gravity (MG), and in particular, Scalar-Tensor (ST) theories, where phantom crossing is a natural and viable feature. We demonstrate these facts by analyzing a joint dataset including DESI DR2, Pantheon+, CMB, and growth-rate (RSD) data in the context of simple parametrizations for the effective gravitational constant, μG(z) Geff/GN, and the DDE equation of state, w(z). This MG framework significantly alleviates the tension, leading to a higher inferred value of H0 = 70.6 1.4 \, km s-1 Mpc-1. We also present a systematic, data-driven reconstruction of the required underlying ST Lagrangian and provide simple, generic analytical expressions for both the non-minimal coupling F(Φ) = 1+ξΦ2enΦ and the scalar potential U(Φ) = U0+aebΦ2, which well-describe the reconstructed functions.