English

Continuous-Variable Entanglement through Central Forces: Application to Gravity between Quantum Masses

Quantum Physics 2023-05-19 v3

Abstract

We describe a complete method for a precise study of gravitational interaction between two nearby quantum masses. Since the displacements of these masses are much smaller than the initial separation between their centers, the displacement-to-separation ratio is a natural parameter in which the gravitational potential can be expanded. We show that entanglement in such experiments is sensitive to initial relative momentum only when the system evolves into non-Gaussian states, i.e., when the potential is expanded at least up to the cubic term. A pivotal role of force gradient as the dominant contributor to position-momentum correlations is demonstrated. We establish a closed-form expression for the entanglement gain, which shows that the contribution from the cubic term is proportional to momentum and from the quartic term is proportional to momentum squared. From a quantum information perspective, the results find applications as a momentum witness of non-Gaussian entanglement. Our methods are versatile and apply to any number of central interactions expanded to any order.

Keywords

Cite

@article{arxiv.2206.12897,
  title  = {Continuous-Variable Entanglement through Central Forces: Application to Gravity between Quantum Masses},
  author = {Ankit Kumar and Tanjung Krisnanda and P. Arumugam and Tomasz Paterek},
  journal= {arXiv preprint arXiv:2206.12897},
  year   = {2023}
}

Comments

accepted for publication in the "Quantum" journal

R2 v1 2026-06-24T12:04:24.711Z