English

A Diamagnetic, Light-Driven Tesla Engine Based on a Mechanically Displaced, Magnetically Levitated Graphene Disk

Applied Physics 2026-04-28 v1 Materials Science Optics

Abstract

Ferromagnetic materials are widely used in Tesla thermomagnetic engines, whereas diamagnetic counterparts have remained unexplored. Here, we demonstrate the first diamagnetic Tesla engine by exploiting the strong diamagnetism of graphene. A graphene disk, fabricated by stacking graphene sheets, serves as the engine wheel. We first show that the conventional Tesla engine design using a permanent magnet placed near the disk edge to create unbalanced thermomagnetic forces under asymmetric local heating fails to generate rotation. We achieve stable operation by laterally displacing the levitated disk from equilibrium, creating a strong restoring force that drives rotation under light excitation. Calculations and measurements establish the displacement-dependent force, with an optimal offset of 0.8 mm yielding speeds up to 2000 rpm under laser heating and 1000 rpm under direct sunlight. Adding vanes allows the disk to function as a gear, powering a graphene vehicle and transferring energy to another disk. This design utilizes the strong and anisotropic diamagnetism of graphene and paves the way for light-powered sensors, actuators, and micro-vehicles.

Cite

@article{arxiv.2604.22803,
  title  = {A Diamagnetic, Light-Driven Tesla Engine Based on a Mechanically Displaced, Magnetically Levitated Graphene Disk},
  author = {Tian Tong and Feng Lin and Wei Zhang and Runjia Li and Xinxin Xing and Zhuochen Duan and Chunhui Xu and Bing Tu and Zhaoping Liu and Xufeng Zhou and Zhiming Wang and Dong Liu and Jonathan Hu and Jiming Bao},
  journal= {arXiv preprint arXiv:2604.22803},
  year   = {2026}
}

Comments

17 pages, 5 figures

R2 v1 2026-07-01T12:34:13.297Z