Published June 5, 2026 | Version v1.0
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The Hidden Architecture of the Universe: Dark Matter, Structural Memory, and the Cosmic Backbone

Authors/Creators

  • 1. Independent researcher

Description

This paper proposes a structural interpretation of the Universe in which dark matter is not treated as a single particle species but as an emergent manifestation of deeper organizational principles in spacetime. The framework introduces the concept of “structural memory,” suggesting that large-scale cosmic evolution may preserve encoded information about past states of matter distribution and gravitational configuration.

Within this perspective, the Universe is modeled as a layered architecture where visible baryonic matter traces only the surface expression of a deeper “cosmic backbone.” This backbone is hypothesized to govern large-scale structure formation, filamentary networks, and galaxy clustering through persistent non-local constraints embedded in spacetime geometry.

The work synthesizes ideas from cosmology, complex systems, and information theory, aiming to reinterpret dark matter phenomenology as an effective observational signature of underlying structural dynamics rather than a standalone physical substance. The framework remains phenomenological and does not replace existing ΛCDM results, but offers an alternative interpretative layer for future theoretical and observational exploration.

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The Hidden Architecture of the Universe: Dark Matter, Structural Memory, and the Cosmic Backbone.pdf

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Preprint: 10.5281/zenodo.20553697 (DOI)

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