Beyond the Born rule in quantum gravity

Abstract

We have recently developed a new understanding of probability in quantum gravity. In this paper we provide an overview of this new approach and its implications. Adopting the de Broglie-Bohm pilot-wave formulation of quantum physics, we argue that there is no Born rule at the fundamental level of quantum gravity with a non-normalisable Wheeler-DeWitt wave functional . Instead the universe is in a perpetual state of quantum nonequilibrium with a probability density P≠ 2. Dynamical relaxation to the Born rule can occur only after the early universe has emerged into a semiclassical or Schr\"odinger approximation, with a time-dependent and normalisable wave functional , for non-gravitational systems on a classical spacetime background. In that regime the probability density can relax towards 2 (on a coarse-grained level). Thus the pilot-wave theory of gravitation supports the hypothesis of primordial quantum nonequilibrium, with relaxation to the Born rule taking place soon after the big bang. We also show that quantum-gravitational corrections to the Schr\"odinger approximation allow quantum nonequilibrium ≠ 2 to be created from a prior equilibrium (= 2) state. Such effects are very tiny and difficult to observe in practice.

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