When does entanglement through gravity imply gravitons?
Abstract
Detection of entanglement through the Newtonian potential has been claimed to support the existence of gravitons, by extrapolating to a thought experiment which demonstrates that complementarity and causality would be in conflict unless quantum fluctuations exist. We critically assess this consistency argument using scalar field models. We show that whether complementarity or no-signalling is violated when quantum fluctuations are neglected, depends on how this approximation is taken, while in both cases entanglement is generated locally in spacetime. We clarify that the correct reading of the paradox requires making a clear distinction between two notions of causality violation: Newtonian action-at-a-distance and the quantum mechanical no-signalling; the latter is pertinent while the former is not. We conclude that the thought experiment (a) does not add to the epistemological relevance of entanglement through Newtonian potentials (b) lends support for the existence of gravitons, if retardation effects are detected in entanglement through gravity.
Keywords
Cite
@article{arxiv.2601.03214,
title = {When does entanglement through gravity imply gravitons?},
author = {Nikolaos Mitrakos and Maria Papageorgiou and T. Rick Perche and Marios Christodoulou},
journal= {arXiv preprint arXiv:2601.03214},
year = {2026}
}
Comments
1 figure (minor clarifications with respect to V1)