Quantifying the Sources of Ionosphere Day‐To‐Day Variability

Quantifying the Sources of Ionosphere Day‐To‐Day Variability

Simulations from the coupled Whole Atmosphere Model and Global Ionosphere Plasmasphere show significant day‐to‐day variations in total electron content (TEC) and the F region peak density (NmF2). The Whole Atmosphere Model‐Global Ionosphere Plasmasphere was driven by the auroral precipitation patter...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics Vol. 123; no. 11; pp. 9682 - 9696
Main Authors: Fang, Tzu‐Wei, Fuller‐Rowell, Tim, Yudin, Valery, Matsuo, Tomoko, Viereck, Rodney
Format: Journal Article
Language:English
Published: Washington Blackwell Publishing Ltd 01-11-2018
Subjects:
Atmosphere
Atmospheric models
Computer simulation
Density
F region
Geomagnetic activity
Geomagnetism
Interplanetary magnetic field
Ionosphere
ionosphere variability
Ionospheric models
Irradiance
Irradiance measurements
Latitude
Lower atmosphere
Magnetic fields
Magnetosphere
Magnetospheres
Photoionization
Plasmasphere
Precipitation
Precipitation patterns
Satellite observation
Solar activity
Solar EUV
Solar irradiance
Solar irradiance measurements
Solar magnetic field
Solar wind
Solar wind parameters
thermosphere variability
Total Electron Content
Variability
whole atmosphere modeling
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Summary:Simulations from the coupled Whole Atmosphere Model and Global Ionosphere Plasmasphere show significant day‐to‐day variations in total electron content (TEC) and the F region peak density (NmF2). The Whole Atmosphere Model‐Global Ionosphere Plasmasphere was driven by the auroral precipitation patterns inferred from TIROS/NOAA, daily solar irradiance measurements derived from the satellite observations, and 5‐min interplanetary magnetic field/solar wind parameters during June and July 2012. Overall, the combination of solar, magnetosphere, and lower atmosphere drivers produced similar magnitude of variability consistent with that seen in observations. Results also show that the relative variability is much larger at night than in the daytime, due to much lower background density, and depended strongly on latitude and local time. Additional simulations were also performed to distinguish the contributions to the variability from solar activity, geomagnetic activity, and lower atmospheric perturbations. Results show that globally, geomagnetic activity is the main contributor to the NmF2 variability, followed by lower atmosphere perturbation, and then solar activity. For TEC variability, again, geomagnetic activity is the main contributor, followed by solar activity, and then lower atmosphere perturbation. In terms of absolute variability, at low latitudes solar activity dominates the TEC variability, most likely due to the importance of solar EUV driving the changes in ionosphere density through photoionization, while the contributions from the lower atmosphere and geomagnetic activity are almost equally. For the middle‐ and high‐latitude regions, the solar activity and geomagnetic activity are the most important sources for the TEC variability. Key Points Simulation reproduces reasonable day‐to‐day variability compared to previous observations Geomagnetic activity is the main contributor to the relative ionospheric variability Ionospheric variability shows significant longitudinal, latitudinal, and local time dependency
ISSN:2169-9380
2169-9402
DOI:10.1029/2018JA025525