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Observing evolution from steady state

General Physics 2024-06-11 v6

Abstract

The time-translation symmetry of the conformal FLRW frame gˉ=a2g\bar{g}=a^{-2}g allows reinterpretation of cosmological observation in the static space of a stationary universe, where constant matter density ρˉm=ρm0\bar{\rho}_{\textrm{m}}=\rho_{\textrm{m0}} induces constant curvature R02R_{0}^{-2}. A hyperbolic de Sitter solution arises from equipartition of the kinetic energy of recessional and peculiar components of the gravitational field, corresponding to a total density 24R0224R_{0}^{-2} of twice the scalar curvature. This predicts a matter density Ωm=124\Omega_{\textrm{m}}=\frac{1}{24}, or a Hubble constant h=24ρm00.72h=\sqrt{24\rho_{\textrm{m0}}}\approx0.72, in agreement with distance-ladder estimates. Projecting the equilibrium state onto the ΛCDM\Lambda\textrm{CDM} model returns h^=4312ρm00.68\hat{h}=\frac{4}{3}\sqrt{12\rho_{\textrm{m0}}}\approx0.68 and exact densities Ω^m=1Ω^Λ=[sinh(43asinh(1))2+1]1=0.3179...\hat{\Omega}_{\textrm{m}}=1-\hat{\Omega}_{\Lambda}=[\textrm{sinh}(\frac{4}{3}\textrm{asinh}(1))^{2}+1]^{-1}=0.3179..., within confidence limits of Planck 2018 results.

Keywords

Cite

@article{arxiv.1903.04894,
  title  = {Observing evolution from steady state},
  author = {Herman Telkamp},
  journal= {arXiv preprint arXiv:1903.04894},
  year   = {2024}
}

Comments

5 pages

R2 v1 2026-06-23T08:05:34.789Z