Typical Quantum States of the Universe are Observationally Indistinguishable

TL;DR

This paper proves that, under typical conditions, the quantum state of the universe is fundamentally indistinguishable through observations, imposing strict limits on our knowledge and measurement capabilities regarding the universe's quantum state.

Contribution

It establishes the strongest known epistemic constraints on the universal quantum state using a typicality theorem in quantum statistical mechanics.

Findings

Observations cannot significantly identify the universal state vector.

Most measurement outcomes do not favor one state vector over others.

Bayesian updates have negligible effects on the initial state distribution.

Abstract

We establish three impossibility results regarding our knowledge of the quantum state of the universe. Suppose the universal quantum state is a typical unit vector in a high-dimensional subspace $\mathscr{H}_0$ of Hilbert space $\mathscr{H}$, such as the low-entropy subspace defined by the Past Hypothesis. We show that: (1) Any particular observation is incapable of identifying the universal state vector in $\mathscr{H}_0$ or substantially reducing the set of possibilities. In other words, the overwhelming majority of possible state vectors are observationally indistinguishable from each other. (2) For any reasonably probable measurement outcome and for most pairs of vectors in $\mathscr{H}_0$, that outcome will not appreciably favor one vector over the other. (3) Bayesian updating on any measurement result, unless it is extraordinarily improbable, has a negligible effect on the initial uniform probability distribution over the states in $\mathscr{H}_0$. These findings represent the most stringent epistemic constraints known for a quantum universe and are derived from a typicality theorem in quantum statistical mechanics. We close by considering how theoretical considerations beyond empirical evidence might inform our understanding of this fact and our knowledge of the universal quantum state.