English

Diamagnetic microchip traps for levitated nanoparticle entanglement experiments

Quantum Physics 2025-11-25 v2 High Energy Physics - Phenomenology

Abstract

The Quantum Gravity Mediated Entanglement (QGEM) protocol offers a novel method to probe the quantumness of gravitational interactions at non-relativistic scales. This protocol leverages the Stern-Gerlach effect to create O(μm)\mathcal{O}(\sim \mu m) spatial superpositions of two nanodiamonds (mass 1015\sim 10^{-15} kg) with NV spins, which are then allowed to interact and become entangled solely through the gravitational interaction. Since electromagnetic interactions such as Casimir-Polder and dipole-dipole interactions dominate at this scale, screening them to ensure the masses interact exclusively via gravity is crucial. In this paper, we propose using magnetic traps based on micro-fabricated wires, which provide strong gradients with relatively modest magnetic fields to trap nanoparticles for interferometric entanglement experiments. The design consists of a small trap to cool the center-of-mass motion of the nanodiamonds and a long trap with a weak direction suitable for creating macroscopic superpositions. In contrast to permanent-magnet-based long traps, the micro-fabricated wire-based approach allows fast switching of the magnetic trapping and state manipulation potentials and permits integrated superconducting shielding, which can screen both electrostatic and magnetic interactions between nanodiamonds in a gravitational entanglement experiment. The setup also provides a possible platform for other tests of quantum coherence in macroscopic systems and searches for novel short-range forces.

Keywords

Cite

@article{arxiv.2411.02325,
  title  = {Diamagnetic microchip traps for levitated nanoparticle entanglement experiments},
  author = {Shafaq Gulzar Elahi and Martine Schut and Andrew Dana and Alexey Grinin and Sougato Bose and Anupam Mazumdar and Andrew Geraci},
  journal= {arXiv preprint arXiv:2411.02325},
  year   = {2025}
}

Comments

11 pages, 8 figures, minor revisions, accepted for publication in Phys. Rev. A

R2 v1 2026-06-28T19:47:43.933Z