Invariant Set Theory

Abstract

Invariant Set Theory (IST) is a realistic, locally causal theory of fundamental physics which assumes a much stronger synergy between cosmology and quantum physics than exists in contemporary theory. In IST the (quasi-cyclic) universe U is treated as a deterministic dynamical system evolving precisely on a measure-zero fractal invariant subset IU of its state space. In this approach, the geometry of IU, and not a set of differential evolution equations in space-time MU, provides the most primitive description of the laws of physics. As such, IST is non-classical. The geometry of IU is based on Cantor sets of space-time trajectories in state space, homeomorphic to the algebraic set of p-adic integers, for large but finite p. In IST, the non-commutativity of position and momentum observables arises from number theory - in particular the non-commensurateness of φ and φ. The complex Hilbert Space and the relativistic Dirac Equation respectively are shown to describe IU, and evolution on IU, in the singular limit of IST at p=∞; particle properties such as de Broglie relationships arise from the helical geometry of trajectories on IU in the neighbourhood of MU. With the p-adic metric as a fundamental measure of distance on IU, certain key perturbations which seem conspiratorially small relative to the more traditional Euclidean metric, take points away from IU and are therefore unphysically large. This allows (the -epistemic) IST to evade the Bell and Pusey et al theorems without fine tuning or other objections. In IST, the problem of quantum gravity becomes one of combining the pseudo-Riemannian metric of MU with the p-adic metric of IU. A generalisation of the field equations of general relativity which can achieve this is proposed.