Electromagnetic wave transmittance control using self-organized plasma lattice metamaterial
Abstract
A reconfigurable glow discharge plasma lattice structure is examined for its ability to interact with and suppress electromagnetic (EM) wave energy with wavelengths on the order of centimeters. The plasma lattice is formed in the air gap between a double dielectric electrode arrangement that formed a rectangular cross-section channel. The lattice consists of columns that span the gap between the electrodes. The spacing between the plasma columns in the lattice results from a surface charge instability that is controllable by a combination of channel height, AC voltage, and gas pressure. The lattice number is highly repeatable and predictable following packing theory. The effect of the plasma lattice spacing on the transmittance of O(cm) wavelength EM waves was investigated. Excellent agreement was found between the experiments and simulations, with S21 transmittance reduced by up to 75%. In addition, experiments in which the EM waves were oriented at an oblique angle to the plasma lattice incident axis were performed. This documented a narrow-band absorption that was predicted from an anisotropic medium permittivity tensor analysis. These experiments also indicated a negative index of refraction of the oblique EM waves for the plasma lattice that provided further evidence of its anisotropic behavior.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Sep 06, 2018
- Source ID
- 10.1063/1.5037469
Entities
People
- Anthony J. Hoffman
- Brian Neiswander
- Eric H. Matlis
- Thomas C. Corke
Organizations
- Air Force Office of Scientific Research
- University of Notre Dame