We strengthen the unified model of emergent gravity (discrete relational networks + Chameleon Scalar-Tensor Gravity) by providing an analytical estimate of the scaling relation γ = ½ (L/λ), a comprehensive finite-size scaling analysis, and quantitative observational predictions. Using simulations of Watts–Strogatz networks with up to N∼10⁴ nodes, we show that the critical attractor L/λ = 4 is approached as N → ∞, with an extrapolated infinite-size value L/λ = 3. 894 ± 0. 009 (deviation 2. 6%). We compute the growth rate fσ₈ (z), the scale-dependent matter power spectrum P (k), the stochastic gravitational wave background ΩGW, the time variation of G, and discuss how the discrete nature of the network avoids curvature singularities. A new appendix validates numerically the conjecture that local clustering maps to Ollivier–Ricci curvature (Pearson correlation r → 0. 964 for N=500), supporting the conformal coupling ξ = 1/6. All predictions are presented with realistic uncertainty ranges and are falsifiable with upcoming surveys (DESI, Euclid, LISA, SKA).
Juan Carlos Alves Tabernero (Sat,) studied this question.
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