Characterization of the energy-dependent response of riometer absorption

Ground‐based riometers provide an inexpensive means to continuously remote sense the precipitation of electrons in the dynamic auroral region of Earth's ionosphere. The energy‐dependent relationship between riometer absorption and precipitating electrons is thus of great importance for understa...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2015-01, Vol.120 (1), p.615-631
Main Authors: Kellerman, A. C., Shprits, Y. Y., Makarevich, R. A., Spanswick, E., Donovan, E., Reeves, G.
Format: Article
Language:English
Subjects:
Absorption
Correlation analysis
cosmic noise absorption
Drift
Electric fields
electron energy
electron precipitation
Energy
Geophysics
Ionosphere
particle modeling
Precipitation
radiation belts
riometer
Riometers
Signatures
Solar cycles
Stations
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Summary:Ground‐based riometers provide an inexpensive means to continuously remote sense the precipitation of electrons in the dynamic auroral region of Earth's ionosphere. The energy‐dependent relationship between riometer absorption and precipitating electrons is thus of great importance for understanding the loss of electrons from the Earth's magnetosphere. In this study, statistical and event‐based analyses are applied to determine the energy of electrons to which riometers chiefly respond. Time‐lagged correlation analysis of trapped to precipitating fluxes shows that daily averaged absorption best correlates with ∼60 keV trapped electron flux at zero‐time lag, although large variability is observed across different phases of the solar cycle. High‐time resolution statistical cross‐correlation analysis between signatures observed by riometer stations, and assuming electron motion due to gradient and curvature drift, results in inferred energies of 10–100 keV, with a clear maximum in occurrence for 40–60 keV electrons. One event is considered in detail utilizing riometer absorption signatures obtained from several stations. The mean inferred energies for the initial rise time and peak of the absorption after correction for electric field effects were ∼70 keV and ∼60 keV, respectively. The analyses presented provide a means to characterize the energy of electrons to which riometers are responding in both a statistical sense and during the evolution of individual events. Key Points Riometer absorption responds to 10–100 keV with peak response at 40–60 keV Method for determining precipitation energy statistically and for specific events CNA has a negligible statistical response to MeV electrons
ISSN:2169-9380
2169-9402
DOI:10.1002/2014JA020027