The Dilaton: A Natural Resolution to the Hubble Tension via Spontaneous Scale Symmetry Breaking

Abstract

The statistical tension between early and late universe measurements of the Hubble constant (H0) suggests that the dark sector is dynamical rather than static. We propose that this dynamics arises from a fundamental symmetry principle: the Spontaneous Breaking of Scale Invariance. We introduce the Dilaton (), a Pseudo-Nambu-Goldstone Boson (PNGB) associated with dilatation symmetry breaking. We demonstrate that a simple quadratic mass term in the fundamental theory transforms, via conformal coupling to gravity, into a ''thawing'' exponential potential V(φ) e-λφ in the Einstein frame. Using recent Bayesian reconstructions of dark energy dynamics from Planck, Pantheon+, and SH0ES data, we constrain the potential slope to be λ ≈ 0.056. We show that this observational value is not arbitrary but corresponds to a fundamental non-minimal coupling strength of ≈ 7.8 × 10-4. The Dilaton mechanism naturally generates the late-time equation of state evolution (w0 ≈ -0.85) required to alleviate the Hubble tension while protecting the field mass m H0 through approximate shift symmetry.