What question did this study set out to answer?

To explore the concept that dark matter is an informational residue from scalar-field-driven cosmic expansion rather than a particle.

March 19, 2026Open Access

Dark Matter as Thermodynamic Informational Residue of Scalar-Field-Driven Cosmic Expansion

Key Points

To explore the concept that dark matter is an informational residue from scalar-field-driven cosmic expansion rather than a particle.
Develop a theoretical model involving a minimally coupled scalar information field.
Analyze irreversible quantum-to-classical transitions causing the formation of a pressureless fluid.
Determine the energy density equation relevant to dark matter.
Predict the behavior of dark matter fraction at different redshifts.
Established dark matter as a cold fluid with energy density scaling as a^(-3).
Showed that the model aligns with current cold dark matter observations.
Predicted that the current dark matter fraction should converge to approximately 0.38 at higher redshifts.

Abstract

We propose that dark matter is not a particle species but the accumulated entropic residue of scalar-field-driven cosmic expansion. A minimally coupled scalar information field S (x, t) coupled to Einstein gravity generates, through irreversible quantum-to-classical transitions, a pressureless fluid with energy density ρDM satisfying dρDM/dt + 3H ρDM = (1-η) β Ṡ² where η = e^-X is the efficiency function and X = I/B is the informational saturation fraction. This residue is cold (w = 0), scales as a^-3, produces no electromagnetic emission, and generates gravitational effects consistent with all current CDM observations. The model reduces to ΛCDM in the limit η → 1. A key prediction: the present dark matter fraction ΩDM ≈ 0. 27 should converge toward Σc ≈ 0. 38 at higher redshifts (z > 2), testable with Euclid and DESI.

Dark Matter as Thermodynamic Informational Residue of Scalar-Field-Driven Cosmic Expansion

Key Points

Abstract

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