The Hubble parameter of the Local Distance Ladder from dynamical dark energy with no free parameters

Abstract

Our cosmology contains Big Bang relic fluctuations by a loss of time-translation symmetry on a Hubble time scale. The contribution to the vacuum is identified with dynamical dark energy αp0 by an IR coupling αp of the bare cosmological constant 0-1 consistent with general relativity, where is the Planck constant. Described by the trace J=(1-q)H2 of the Schouten tensor derived from a path integral formulation with gauged global phase, the proposed JCDM takes us beyond the limit of frozen J=. The Hubble constant H0 in JCDM is effectively 6/5 times the Planck value in analysis of the CMB according to H(z)=H01+(6/5)M,0 Z5(z) + r,0Z6(z)/(1+z), where Zn=(1+z)n-1 given densities of matter M,0 and radiation r,0. With no free parameters, JCDM hereby agrees with the Local Distance Ladder when satisfying the BAO measured by Planck. On this cosmological background, galaxies possess an essentially C0-transition to anomalous dynamics due to reduced inertia below the de Sitter scale of acceleration adS=cH, where c is the velocity of light. This is confirmed in SPARC over a 6σ tension in galaxy models, pointing to ultra-light CDM of mass mDc2<3× 10-21eV. Sensitivity to this cosmological background explains the JWST 'Impossible galaxies' at cosmic dawn by rapid gravitational collapse. We comment on an outlook on future confrontations with observations by Euclid.