What question did this study set out to answer?

The aim is to provide a unified framework where spacetime, matter, and quantum mechanics emerge from a microscopic copying process.

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April 11, 2026Open Access

Information-Copying Cosmology: Emergent Unitarity, Effective Cosmological Constant, and a Testable Expansion Law

Key Points

The aim is to provide a unified framework where spacetime, matter, and quantum mechanics emerge from a microscopic copying process.
Proposed a framework based on local copying of a simplicial complex with stochastic defects.
Analyzed the emergence of Hubble expansion and cosmological constant from microscopic processes.
Derived the Schrödinger equation under diffusive scaling and investigated stochastic phase averaging.
Predicted Hubble expansion as H = D0/3.
Established cosmological constant as Λ = D02/(3c2) without fine-tuning.
Identified a new expansion law H(z) ∼ (1 + z)3/2 at z > 2, indicating deviation from ΛCDM model.

Abstract

We propose a unified framework in which spacetime, matter fields, and quantum mechanics emerge from a discrete microscopic process: local copying of a simplicial complex with stochastic defects. We demonstrate that: (i) exponential growth of vertices yields Hubble expansion H = D0/3, (ii) the cosmological constant emerges as Λ = D02/(3c2) without fine-tuning, (iii) the Schr¨odinger equation arises in the continuum limit under diffusive scaling, (iv) the Born rule and Lindblad decoherence follow from stochastic phase averaging. The model predicts a distinct deviation from ΛCDM expansion: H(z) ∼ (1 + z)3/2 at z > 2, at the 5–10% level, testable by DESI and Euclid. Units: c = 1 unless stated otherwise.

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