Title :
RF-Induced Airglow Observed Using Composite Multispectral Imaging
Author :
Holmes, Jeffrey M. ; Pedersen, Todd R. ; Mills, Travis J.
Author_Institution :
Space Vehicles Directorate, Air Force Res. Lab., Kirtland AFB, NM, USA
Abstract :
Atmospheric airglow emissions accompanying artificial ionospheric plasmas occur when the bottom-side ionospheric F-region is exposed to high-power HF heating. These artificial emissions are spectrally similar to those which occur naturally as airglow and aurora, yet they have spatiotemporal behavior commensurate with the heater beam geometry. Interesting dynamics of both the artificial plasma layers and optical emissions have been observed, namely, the presence of multiple descending plasma layers distributed in altitude, mesoscale (10-100 km) bullseye-type airglow emission patterns, and, finally, small-scale (≲ 10 km) field-aligned filaments. We present visualizations of such features exhibited by the heated region using composite multispectral imaging.
Keywords :
F-region; HF radio propagation; airglow; atmospheric electromagnetic wave propagation; aurora; ionospheric techniques; plasma radiofrequency heating; spectral analysis; RF-induced airglow; altitude 10 km to 100 km; artificial plasma layer; atmospheric airglow emission; aurora; bottom-side ionospheric F-region; composite multispectral imaging; heated region; heater beam geometry; high-power HF heating; ionospheric plasma; mesoscale bullseye-type airglow emission pattern; multiple descending plasma layer; optical emission; small-scale field-aligned filament; spatiotemporal behavior; Green products; Heating; Image color analysis; Optical imaging; Optical transmitters; Plasmas; Stimulated emission; Ionosphere; multispectral imaging; optical imaging; plasma density;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2011.2158854
