When gravitational fields are at their strongest, the evolution of spacetime is thought to be highly erratic. Over the past decade debate has raged over whether this evolution can be classified as chaotic. The debate has centered on the homogeneous but anisotropic mixmaster universe. A definite resolution has been lacking as the techniques used to study the mixmaster dynamics yield observer dependent answers. Here we resolve the conflict by using observer independent, fractal methods. We prove the mixmaster universe is chaotic by exposing the fractal strange repellor that characterizes the dynamics. The repellor is laid bare in both the 6-dimensional minisuperspace of the full Einstein equations, and in a 2-dimensional discretisation of the dynamics. The chaos is encoded in a special set of numbers that form the irrational Farey tree. We quantify the chaos by calculating the strange repellor's Lyapunov dimension, topological entropy and multifractal dimensions. As all of these quantities are coordinate, or gauge independent, there is no longer any ambiguity--the mixmaster universe is indeed chaotic.
[1]
Adrian B. Burd,et al.
Deterministic chaos in general relativity
,
1994
.
[2]
Neil Gershenfeld,et al.
Information In Dynamics
,
1992,
Workshop on Physics and Computation.
[3]
Manfred Schroeder,et al.
Fractals, Chaos, Power Laws: Minutes From an Infinite Paradise
,
1992
.
[4]
Mw Hirsch,et al.
Chaos In Dynamical Systems
,
2016
.
[5]
D. Raine.
General relativity
,
1980,
Nature.
[6]
Reza Mansouri,et al.
General Relativity and Gravitation: A Centennial Perspective
,
2015
.