Lorenz, G\"{o}del and Penrose: New perspectives on determinism and causality in fundamental physics

TL;DR

This paper introduces an invariant set theory linking chaos, fractal geometry, and fundamental physics, proposing a deterministic universe model that challenges standard quantum and gravitational theories.

Contribution

It develops a new deterministic framework based on fractal invariant sets, integrating chaos theory with cosmology and quantum mechanics, extending general relativity principles.

Findings

The universe can be modeled as a deterministic fractal invariant set.

The theory allows quantum probabilities while violating Bell inequalities.

Proposes a gravitational quantum theory with observational implications for dark matter and dark energy.

Abstract

Despite being known for his pioneering work on chaotic unpredictability, the key discovery at the core of meteorologist Ed Lorenz's work is the link between space-time calculus and state-space fractal geometry. Indeed, properties of Lorenz's fractal invariant set relate space-time calculus to deep areas of mathematics such as G\"{o}del's Incompleteness Theorem. These properties, combined with some recent developments in theoretical and observational cosmology, motivate what is referred to as the `cosmological invariant set postulate': that the universe $U$ can be considered a deterministic dynamical system evolving on a causal measure-zero fractal invariant set $I_U$ in its state space. Symbolic representations of $I_U$ are constructed explicitly based on permutation representations of quaternions. The resulting `invariant set theory' provides some new perspectives on determinism and causality in fundamental physics. For example, whilst the cosmological invariant set appears to have a rich enough structure to allow a description of quantum probability, its measure-zero character ensures it is sparse enough to prevent invariant set theory being constrained by the Bell inequality (consistent with a partial violation of the so-called measurement independence postulate). The primacy of geometry as embodied in the proposed theory extends the principles underpinning general relativity. As a result, the physical basis for contemporary programmes which apply standard field quantisation to some putative gravitational lagrangian is questioned. Consistent with Penrose's suggestion of a deterministic but non-computable theory of fundamental physics, a `gravitational theory of the quantum' is proposed based on the geometry of $I_U$, with potential observational consequences for the dark universe.