Relativity without relativity

TL;DR

This paper derives general relativity and gauge principles without assuming spacetime or relativity principle, showing spacetime symmetry as emergent and deriving Einstein causality and Maxwell equations from internal consistency.

Contribution

It presents a novel derivation of GR and gauge theories from actions on superspace with minimal assumptions, highlighting emergent spacetime symmetry and causality.

Findings

Spacetime symmetry emerges as a hidden symmetry in solutions.

Constraint propagation enforces Einstein causality for scalar fields.

Maxwell equations are derived from consistency conditions.

Abstract

We give a derivation of general relativity and the gauge principle that is novel in presupposing neither spacetime nor the relativity principle. We consider a class of actions defined on superspace with two key properties. The first is 3-coordinate invariance. This is the only postulated symmetry, and it leads to the standard momentum constraint. The second property is that the Lagrangian is constructed from a `local' square root of an expression quadratic in the velocities, `local' because it is taken before integration over 3-space. It gives rise to quadratic constraints that do not correspond to any symmetry and are not, in general, propagated by the Euler-Lagrange equations. Therefore these actions are internally inconsistent. Only one action of this form is well behaved: the Baierlein-Sharp-Wheeler reparametrisation-invariant action for GR. From this viewpoint, spacetime symmetry is emergent. It appears as a `hidden' symmetry in the (underdetermined) solutions of the evolution equations, without being manifestly coded into the action itself. In addition, propagation of the constraints acts as a striking selection mechanism beyond pure gravity. If a scalar field is included in the configuration space, it must have the same characteristic speed as gravity. Thus Einstein causality emerges. Finally, self-consistency requires that any 3-vector field must satisfy Einstein causality, the equivalence principle and, in addition, the Gauss constraint. Therefore we recover the standard (massless) Maxwell equations.