Title :
Minimum sprite plasma density as determined by VLF scattering
Author :
Dowden, R.L. ; Rodger, C.J. ; Nunn, D.
Author_Institution :
LF-EM Res. Ltd., Dunedin, New Zealand
fDate :
4/1/2001 12:00:00 AM
Abstract :
The scattering of VLF sub-ionospheric transmissions by sprite plasma through horizontal angles up to 180/spl deg/ shows that sprite plasma is highly conducting. Following a simple transmission-line (one-dimensional-wave) model in 1997, two-dimensional and three-dimensional models have been produced. Here, we compare the results of the three models, and show that all require a uniform conductivity of at least 30 μS/m, corresponding to an electron density at 70 km altitude of /spl sim/10/sup 10/ m/sup -3/ (/spl sim/104 electrons per cc), and so about 105/cc at 55 km. The latter ionization density is about that of the daytime E-region, and over six orders of magnitude above the ambient density at 55 km. By contrast, the "early/fast" events, as defined by the Stanford group, do not exhibit scatter angles above 15/spl deg/, suggesting that the sprite conductivity rises too slowly (as the plasma cools) to reach adequate backscatter within the time allowed by the "early/fast" definition.
Keywords :
atmospheric electricity; atmospheric ionisation; atmospheric techniques; electromagnetic wave scattering; electron density; ionospheric disturbances; ionospheric electromagnetic wave propagation; plasma density; radiowave propagation; transmission line theory; 55 to 70 km; VLF scattering; VLF sub-ionospheric transmissions; conductivity; electron density; ionization density; minimum sprite plasma density; one-dimensional-wave model; sprite conductivity; three-dimensional models; transmission-line model; two-dimensional models; Conductivity; Electromagnetic scattering; Electrons; Ionization; Light scattering; Nuclear and plasma sciences; Optical scattering; Plasma density; Plasma measurements; Sprites (computer);
Journal_Title :
Antennas and Propagation Magazine, IEEE
