Quantum superposition of spacetimes obeys Einstein's equivalence principle

Flaminia Giacomini,Časlav Brukner

doi:10.1116/5.0070018

Abstract

We challenge the view that there is a basic conflict between the fundamental principles of Quantum Theory and General Relativity and, in particular, the fact that a superposition of massive bodies would lead to a violation of the Equivalence Principle. It has been argued that this violation implies that such a superposition must inevitably spontaneously collapse (like in the Diósi–Penrose model). We identify the origin of such an assertion in the impossibility of finding a local and classical reference frame in which Einstein's Equivalence Principle would hold. In contrast, we argue that the formulation of the Equivalence Principle can be generalized so that it holds for reference frames that are associated with quantum systems in a superposition of spacetimes. The core of this new formulation is the introduction of a quantum diffeomorphism to such Quantum Reference Frames. This procedure reconciles the principle of linear superposition in Quantum Theory with the principle of general covariance and the Equivalence Principle of General Relativity. Hence, it is not necessary to invoke a gravity-induced spontaneous state reduction when a massive body is prepared in a spatial superposition.

Highlights

We challenge the view that there is a basic conflict between the fundamental principles of Quantum Theory and General Relativity, and in particular the fact that a superposition of massive bodies would lead to a violation of the Equivalence Principle
The root of the problem in realising such a spatial superposition of a massive body lies in the incompatibility between the fundamental principles of General Relativity and Quantum Theory: on the one hand, the principle of general covariance and the Equivalence Principle, and on the other hand, the principle of linear superposition
We have introduced the notion of a Quantum Reference Frame (QRF) [18, 41–50], i.e., a reference frame associated to a quantum system, whose state can be in a superposition or entangled with other physical systems

Summary

Introduction

We challenge the view that there is a basic conflict between the fundamental principles of Quantum Theory and General Relativity, and in particular the fact that a superposition of massive bodies would lead to a violation of the Equivalence Principle. According to Penrose’s argument, the validity of the Equivalence Principle is restored via a gravitationally-induced spontaneous state reduction [3, 6, 51]: the quantum superposition of masses, initially in an unstable configuration, evolves into a classical, well-defined spacetime in some time t∆ ≈ E∆ , with E∆ being the gravitational self-energy of the difference between the mass distributions of the two mass configurations.

Results

Conclusion