Entanglement generation and dynamical equilibrium within de Broglie Bohm theory

TL;DR

This paper explores how gravitational interactions within a de Broglie-Bohm framework can generate entanglement and establish a stable dynamical equilibrium, proposing new communication methods based on these insights.

Contribution

It introduces a refined semiclassical gravity model that demonstrates entanglement generation through gravitational feedback, and proposes a novel dynamical equilibrium concept for subsystems.

Findings

Gravitational feedback can induce entanglement even at weak levels.

A new communication scheme leveraging gravitational interactions is proposed.

The concept of dynamical equilibrium provides a stable subsystem strategy.

Abstract

In this work, we reassess our previous hybrid semiclassical gravity model and demonstrate its ability to induce entanglement even in the limit of weak entanglement. By incorporating feedback terms sourced from gravitational potential interactions between subsystems, based on a refined version of Theory of (Exclusively) Local Beables developed by Travis Norsen, we show that these interactions alone can generate entanglement. Building on this insight, we propose a novel communication scheme and introduce the concept of dynamical equilibrium, which formalizes a stable strategy for subsystems. This framework is inspired by the quantum equilibrium hypothesis of de Broglie Bohm theory and causal interpretation of David Bohm and Jean Pierre Vigier.