Quantum Weak Measurements and Cosmology

TL;DR

This paper explores how weak quantum measurements with pre-and-post-selection can impact cosmological models, potentially leading to observable effects and offering a new framework for understanding quantum influences on the universe.

Contribution

It introduces a novel application of weak quantum measurements with pre-and-post-selection to cosmology, proposing observable effects and a new computational framework.

Findings

Potential large and observable effects at the present epoch.

A framework for computing quantum effects in cosmology.

Proposed experimental test for the theory.

Abstract

The indeterminism of quantum mechanics generally permits the independent specification of both an initial and a final condition on the state. Quantum pre-and-post-selection of states opens up a new, experimentally testable, sector of quantum mechanics, when combined with statistical averages of identical weak measurements. In this paper I apply the theory of weak quantum measurements combined with pre-and-post-selection to cosmology. Here, pre-selection means specifying the wave function of the universe or, in a popular semi-classical approximation, the initial quantum state of a subset of quantum fields propagating in a classical back-ground spacetime. The novel feature is post-selection: the additional specification of a condition on the quantum state in the far future. I discuss "natural" final conditions, and show how they may lead to potentially large and observable effects at the present cosmological epoch. I also discuss how pre-and-post-selected quantum contrast to the expectation value of the stress-energy-momentum tensor, resolving a vigorous debate from the 1970's. The paper thus provides a framework for computing large-scale cosmological effects arising from this new sector of quantum mechanics. A simple experimental test is proposed.