Quantum uncertainty of gravitational field and entanglement in superposed massive particles

TL;DR

This paper explores how quantum uncertainty in gravitational and electromagnetic fields influences entanglement between particles, showing that such uncertainty prevents entanglement when causality is maintained, thus supporting the principle of complementarity.

Contribution

The study demonstrates that quantum field uncertainty leads to vacuum fluctuations that inhibit particle entanglement, clarifying the relationship between quantum uncertainty, causality, and complementarity in gravity and electromagnetism.

Findings

Quantum uncertainty causes vacuum fluctuations that prevent entanglement.

Entanglement is prohibited when causality is satisfied.

Complementarity holds when particles are not entangled.

Abstract

Investigating the quantum nature of gravity is an important issue in modern physics. Recently, studies pertaining to the quantum superposition of gravitational potential have garnered significant interest. Inspired by Mari \textit{et al.} [Sci. Rep. {\bf 6} 22777 (2016)] and Baym and Ozawa [Proc. Natl. Acad. Sci. U.S.A. {\bf 106}, 3035 (2009)], Belenchia \textit{et al.} [Phys. Rev. D {\bf 98}, 126009 (2018)] considered a gedanken experiment involving such a quantum superposition and mentioned that the superposition renders causality and complementarity inconsistent. They resolved this inconsistency by considering the quantized dynamical degrees of freedom of gravity. This suggests a strong relationship between the quantum superposition of the gravitational potential and the quantization of the gravitational field. In our previous study [Phys. Rev. D {\bf 106}, 125002 (2022)], we have shown that the quantum uncertainty of a field guarantees the consistency between causality and complementarity. In this study, we focus on the entanglement between two particles' states due to the electromagnetic/gravitational potential and investigate its relationship with quantum uncertainty, causality, and complementarity. Our numerical analyses show that the quantum uncertainty of the electromagnetic/gravitational field results in vacuum fluctuations and prohibits the entanglement between two particles' states when causality is satisfied. We further demonstrate that complementarity holds when the particles do not get entangled. The uncertainty relation does not cause the entanglement between two particles' states, which guarantees complementarity.