Spontaneous Formation of Universes from Vacuum via Information-induced Holograms

TL;DR

This paper proposes a novel principle based on Fisher information to explain the spontaneous emergence of universes from vacuum, linking cosmology, information theory, and holography, and deriving universe expansion laws similar to biological ion equations.

Contribution

It introduces a variational principle of minimum Fisher information to model universe formation and demonstrates how physical constants are preserved across multiverses via holographic relays.

Findings

Universes emerge from vacuum via Fisher information principles.

Expansion laws of universes follow exponential probability densities.

Physical constants are preserved through holographic relays in the multiverse.

Abstract

All spontaneous emergence of quantum particles from false vacuums can occur via usual energy-based Lagrangians; or, as we show, via a variational principle of minimum loss of Fisher information. By this principle all material existence in the multiverse, including its life forms, are physical manifestations of Fisher information. The information principle serially formed our universe, and all others, in the multiverse. The resulting expansionary (Big bang) eras of time t and/or space-time x_i, i = x,y,z,t (c=1) for the universes are found to obey probability densities p(t) and p(x_i) of usual exponential forms. The existence of the multiverse allows preservation of invariant values of the 26 physical constants via their relay from one universe to another by successive Lorentzian wormholes. At each relay the emerging constants are represented by the intensities of an input hologram. The information principle was previously used to derive nearly all textbook physics and much cell biology, e.g. the Hodgkin-Huxley (H-H) equations governing ions emerging into biological cells. The equations we derive governing p(t) and p(x_i) for universes coincide with the H-H equations governing ions entering these biological cells. Thus, the information concept holds over a vast range of scale sizes.