Multivariate Analysis on the Ionospheric Responses to Planetary Waves During the 2019 Antarctic SSW Event

A rare minor sudden stratospheric warming is observed in the Antarctic polar region during September 2019, which results in the enhancement of a westward wavenumber 1 quasi‐6‐day wave (Q6DW) in the mesopause region. The impacts of this Q6DW event to the ionosphere are then comparatively investigated...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2021-03, Vol.126 (3), p.n/a
Main Authors: Gu, Sheng‐Yang, Teng, Chen‐Ke‐Min, Li, Na, Jia, Mingjiao, Li, Guozhu, Xie, Haiyong, Ding, Zonghua, Dou, Xiankang
Format: Article
Language:English
Subjects:
6‐day wave
Amplitudes
BeiDou Navigation Satellite System
Equatorial regions
F 2 region
foF2
Ground-based observation
Ionosondes
Ionosphere
Ionospheric observations
ionospheric variations
Mesopause
Mesosphere
Multivariate analysis
Navigation satellites
Navigation systems
Planetary waves
Polar environments
Polar regions
Stratospheric warming
sudden stratospheric warming
Temperature
Total Electron Content
Wavelengths
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Summary:A rare minor sudden stratospheric warming is observed in the Antarctic polar region during September 2019, which results in the enhancement of a westward wavenumber 1 quasi‐6‐day wave (Q6DW) in the mesopause region. The impacts of this Q6DW event to the ionosphere are then comparatively investigated with multiple data sets, including the ground‐based total electron content (TEC) from geostationary BeiDou satellite receivers and F2 layer maximum frequency (foF2) from ionosondes ranging from 20 to 40°N over eastern Asia. Besides, the global TEC maps from the International Global Navigation Satellite Systems Service (IGS) are also utilized to study the longitudinal variations. The ground‐based TEC and foF2 observations clearly shows planetary wave (PW) signals with a similar period as those in the mesosphere, which are further verified to be westward with zonal wavenumber 1 by IGS TEC maps. The ground‐based TEC and foF2 also show that the peak of the ionospheric response is at around 1,200–1,400 LT and 25°N over eastern Asia with maximum amplitudes of ∼9 TECU and ∼1.5 MHz, respectively, which are also well captured by IGS TEC maps. Nevertheless, the wave amplitudes exhibited by ground‐based TEC are 2–3 times larger than that in IGS TEC. Besides, the IGS TEC map shows that the ionospheric oscillations at different longitudes peak in the equatorial ionospheric anomaly crest region at similar solar local time, but with significant variabilities in their amplitude. Our analysis shows that the ground‐based ionospheric observations and IGS TEC maps generally exhibit consistent latitudinal structures on the neutral‐ion coupling through PWs. Key Points Ground‐based ionospheric observations show maximum planetary wave (PW) responses near the Equatorial Ionization Anomaly crest over eastern Asia Total Electron Content maps and ground‐based ionospheric data sets show consistent results on neutral‐ion coupling through PWs Ionospheric responses to PWs exhibit clear longitudinal variations
ISSN:2169-9380
2169-9402
DOI:10.1029/2020JA028588