The team simulated a system that uses light to generate an electromagnetic field. Neutral nanoparticles made from glass or some other material that insulates rather than conducts electric charges are used. The nanoparticles become polarized. All of the positive charges are displaced in the direction of the field and negative charges shift in the opposite direction. It creates an internal electric field that produces a force to move the particles from a reservoir, funneled through an injector, then shot out of an accelerator to produce thrust.
The study, that has been about eight years in the making, analytically showed that the technique can work, and suggested parameters for success.
The technique is based on a field of physics called plasmonics that studies how optical light or optical electromagnetic waves, interact with nanoscale structures, such as a bar or prism.
Rovey explained when the light hits the nanoscale structure, a resonant interaction occurs. It creates strong electromagnetic fields right next to that structure. And those electromagnetic fields can manipulate particles by applying forces to nanoscale particles that are near those structures. The study focused on how to feed the nanoparticles into the accelerator structure, or injector and how the angles of the plates in the injector affect the forces on these nanoparticles.
“One of the main motivating factors for the concept was the absence of or lack of a power supply in space,” Rovey said. “If we can just harness the sun directly, have the sun shine directly on the nanostructures themselves, there’s no need for an electrical power supply or solar panel to provide power.”
Rovey said this study was a numerical simulation. The next step will be to create nanoscale structures in a lab, load then into the system, apply a light source, and observe how the nanoparticles move.
The study, Nanoparticle injector for photonic manipulators using dielectrophoresis,” was written by Jaykob Maser and Joshua L. Rovey. It appears in AIP Advances. DOI: 10.1063/1.5099520
This project was supported by the Air Force Office of Scientific Research, a grant from the NASA Innovative Advanced Concepts program, and Missouri University of Science and Technology through the Chancellor’s Fellowship.