The equivalence principle and inertial-gravitational decoherence

TL;DR

This paper explores how the equivalence principle influences inertial-gravitational decoherence and argues that decoherence effects may inherently prevent the experimental detection of quantum gravity, highlighting fundamental limitations.

Contribution

It provides a novel analysis of decoherence due to inertial and gravitational effects within quantum systems and discusses the implications for observing quantum gravity phenomena.

Findings

Decoherence from inertial and gravitational backreaction can hinder quantum gravity detection.

The equivalence principle's exact incorporation may inherently cause decoherence.

Speculations on implementing the equivalence principle in quantum field theory.

Abstract

This work is divided into two parts. The first examines recent proposals for "witnessing" quantum gravity via entanglement from the point of view of Bronstein's original objection to a quantization of gravity. Using techniques from open quantum systems we sketch how unavoidable decoherence from both inertial and gravitational backreaction between probe and detector could spoil the experimental detection of the quantization of gravity. We argue that this "failure" is actually an inherent feature of any quantum description that attempts to incorporate the equivalence principle exactly within quantum dynamics. In the second part, we speculate on how an exact realization of the equivalence principle might be implemented in an effective quantum field theory via the general covariance of correlators. While we are far from giving an explicit construction of such a theory we point out some features and consequences of such a program.