What does this research mean for the field?

The empirical galactic acceleration threshold (a_0) can be precisely derived from a two-scale de Sitter cosmological identity that incorporates the dark energy density, matching observed values to the 10^-3 level without requiring free galaxy-level parameters. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to define a new cosmic acceleration scale within the context of a two-scale de Sitter cosmological model.

May 30, 2026Open Access

A Two-Scale de Sitter Identity for the Galactic Acceleration Threshold

Key Points

This research aims to define a new cosmic acceleration scale within the context of a two-scale de Sitter cosmological model.
Developed the cosmic mean acceleration scale ā_∂Λ based on the de Sitter model parameters.
Evaluated the new scale against empirical values, conducting consistency checks.
Validated the model using SPARC RAR data to compare against conventional RAR normalization.
The derived acceleration scale ā_∂Λ equals 1.2006 × 10⁻¹⁰ m/s², aligning closely with the conventional RAR value.
Demonstrated Δχ² ≈ +0.08 in SPARC RAR validation against conventional parameters, indicating robust consistency.
Revealed that this model is not a direct replacement for dark energy, tying galactic dynamics to cosmological backgrounds.

Abstract

The empirical acceleration scale that normalises the radial acceleration relation (RAR) is conventionally written as a₀ ≈ 1. 20 × 10⁻¹⁰ m/s². It marks the scale at which the Newtonian acceleration inferred from the baryonic mass distribution no longer closes the observed galactic acceleration budget. It has long been noted that a₀ lies close to c·H₀/ (2π), although the uncorrected Hubble-temperature scale undershoots the empirical value by about 13%. Working within a two-scale de Sitter cosmological background, we define a cosmic mean acceleration scale ā_∂Λ: = c · Θ₇䃐 · (V_Λ / VH) ^ (1/4) = c · H₀ / 2π · Ω_Λ^ (3/8), where VH is the present Hubble volume, V_Λ the asymptotic de Sitter comparison volume, and Θ₇䃐 = H₀/ (2π) = kB · T₇䃐 / ℏ the Gibbons–Hawking-type Hubble-temperature frequency scale of the present Hubble horizon. Evaluated at Planck 2018 central values, ā_∂Λ = 1. 2006 × 10⁻¹⁰ m/s², in 10⁻³-level agreement with the conventional RAR/Milgrom central normalisation, with no galaxy-level fit parameter. We present this relation as an empirical cosmological identity and test its forward and inverse consistency, including a direct SPARC RAR validation with the cosmological value held fixed (Δχ² ≈ +0. 08 against the free-a₀ optimum; the bare c·H₀/ (2π) scale is disfavoured by Δχ² ≈ +5440 under the same diagnostic). Several equivalent forms expose complementary readings, including a baryon-Hubble form ā_∂Λ ≈ 0. 83 · c · Hb and a Friedmann-sum rewriting in which the baryonic, dark-matter, and dark-energy rates together with ā_∂Λ enter a single dimensionless relation. Within the present ansatz, a finite positive Ω_Λ is required to define the de Sitter comparison horizon: the identity is therefore not a MOND-style replacement of dark energy, and galactic regime closure is tied to the late-time cosmological background within this construction. The identity is offered as a phenomenological cosmological ansatz; the microscopic boundary derivation is reserved for a companion paper.

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