Abstract
We propose a unified cosmological framework that synthesizes three emerging paradigms---the Blink Universe (as a non-singular quantum origin), the Multilayer Multiverse (as the topological structure of inter-universal connections), and the Fractal Universe (as the internal self-similar geometry of each universe)---into a coherent model that addresses several key anomalies in modern cosmology. Motivated by persistent tensions in the value of the Hubble constant, the early alignment of galactic angular momentum, and the discovery of large-scale voids incompatible with CDM, we develop a mathematical formalism that characterizes the universe as a layered topological network of discrete emergent domains ('blinks'), each with internally fractal mass-energy distribution governed by non-integer Hausdorff dimensions.
We show that the apparent low value of the cosmological constant can arise from destructive interference of topological fields propagating across adjacent layers. Further, the fractal geometry within each universe layer naturally induces anisotropies in galaxy spin alignments and large-scale clustering. Initial simulations based on interpolated H(r) profiles within void-centered domains produce consistent patterns with observed early-time structure formation and anisotropic rotation reported by JWST.
This multilayer-fractal-blink model provides testable predictions, such as quantized redshift plateaus, layered lensing anomalies, and spin-correlation maps at void boundaries. We conclude by suggesting pathways to observationally falsify the model using upcoming deep-field surveys (e.g., Euclid, SKA) and discuss its compatibility with extensions of general relativity and quantum gravity frameworks.
Preface: From Spacetime to Information---Reframing the Foundations of Cosmology
"The fundamental fabric of the Universe is not space, nor time, nor matter, nor even energy. It is information."
For over a century, modern physics has relied on two towering frameworks: General Relativity (GR) for describing gravity and the large-scale structure of spacetime, and Quantum Field Theory (QFT) for understanding the microscopic realm of particles and interactions. Despite their immense success, both theories fall short when applied to the most extreme conditions in the Universe---singularities, event horizons, and the earliest moments of the Big Bang. They resist unification.
This work begins from a deceptively simple yet profound question:
What remains invariant when space, time, and even particles dissolve?
The answer is: information.
We propose that information---not spacetime, nor quantum fields---is the true fundamental substrate of the Universe. This shift leads to a radically different framework in which gravitational geometry, quantum fields, and even time itself emerge from deeper informational dynamics.
1. From Holography to Qubit Geometry
The Holographic Principle suggests that the information content of a volume of space can be encoded on its boundary surface, implying that reality itself may be a projection of lower-dimensional information. The AdS/CFT correspondence goes further, equating a gravitational theory in anti-de Sitter space with a non-gravitational conformal field theory on its boundary.
