Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals

Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals

The response of the global ionosphere to solar flares is an important topic in the field of space weather. The global ionospheric response to solar flares is comprehensively analyzed from the perspectives of total electron content (TEC) and very low frequency (VLF) signals by using solar flare data...

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Main Authors: Jiandi Feng, Baomin Han, Feng Gao, Ting Zhang, Zhenzhen Zhao
Format: Article
Language:English
Published: IEEE 2021-01-01
Series:IEEE Access
Subjects:
Disturbance intensity
ionosphere
solar flare
total electron content
very low frequency signals
Online Access:https://ieeexplore.ieee.org/document/9400368/
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spelling doaj-c07fce9d85524b45b8d70bf5d735d0c82021-04-19T23:01:23ZengIEEEIEEE Access2169-35362021-01-019576185763110.1109/ACCESS.2021.30724279400368Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency SignalsJiandi Feng0https://orcid.org/0000-0002-0054-6690Baomin Han1Feng Gao2Ting Zhang3Zhenzhen Zhao4School of Civil and Architectural Engineering, Shandong University of Technology, Zibo, ChinaSchool of Civil and Architectural Engineering, Shandong University of Technology, Zibo, ChinaSchool of Civil and Architectural Engineering, Shandong University of Technology, Zibo, ChinaSchool of Civil and Architectural Engineering, Shandong University of Technology, Zibo, ChinaSchool of Civil and Architectural Engineering, Shandong University of Technology, Zibo, ChinaThe response of the global ionosphere to solar flares is an important topic in the field of space weather. The global ionospheric response to solar flares is comprehensively analyzed from the perspectives of total electron content (TEC) and very low frequency (VLF) signals by using solar flare data on the eruption days of X-class flares from 2006 to 2019, including flare level, flare duration, geographical location, and local time. In addition, the relationship between X-ray flux and VLF phase variation is studied through correlation analysis. The concepts of disturbance intensity (DI) and disturbance angle are defined, and a DI evaluation model is established to help detect the difference in sensitivity to solar flares between TEC and VLF signals. Results show the following. (1) The higher the flare level and the longer the duration, the greater the disturbance to the ionosphere. Simultaneously, a phenomenon exists in which the disturbance caused by low-level and long-lasting flares is greater than that caused by high-level flares. (2) VLF phase variation and flare level exhibit a good correlation, and they are also closely related to geographical location and local time. The disturbance degree of a station facing the sun is more evident than that of a station facing away from the sun. The TEC disturbance of stations in the morning (local time) is more obvious than that in the afternoon, and disturbance increases along the direction of Earth’s rotation. (3) When DI is at the same level, the lowest flare level that causes TEC response is higher than the lowest flare level that causes VLF signal response. The disturbance angle of TEC is unevenly distributed within the interval [0°, 90°], and that of VLF signals is more than 85°. The sensitivity of VLF signals to flare response is considerably higher than that of TEC, and the difference between the two even stride across DI level.https://ieeexplore.ieee.org/document/9400368/Disturbance intensityionospheresolar flaretotal electron contentvery low frequency signals
collection DOAJ
language English
format Article
sources DOAJ
author Jiandi Feng
Baomin Han
Feng Gao
Ting Zhang
Zhenzhen Zhao
spellingShingle Jiandi Feng
Baomin Han
Feng Gao
Ting Zhang
Zhenzhen Zhao
Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals
IEEE Access
Disturbance intensity
ionosphere
solar flare
total electron content
very low frequency signals
author_facet Jiandi Feng
Baomin Han
Feng Gao
Ting Zhang
Zhenzhen Zhao
author_sort Jiandi Feng
title Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals
title_short Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals
title_full Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals
title_fullStr Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals
title_full_unstemmed Analysis of Global Ionospheric Response to Solar Flares Based on Total Electron Content and Very Low Frequency Signals
title_sort analysis of global ionospheric response to solar flares based on total electron content and very low frequency signals
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2021-01-01
description The response of the global ionosphere to solar flares is an important topic in the field of space weather. The global ionospheric response to solar flares is comprehensively analyzed from the perspectives of total electron content (TEC) and very low frequency (VLF) signals by using solar flare data on the eruption days of X-class flares from 2006 to 2019, including flare level, flare duration, geographical location, and local time. In addition, the relationship between X-ray flux and VLF phase variation is studied through correlation analysis. The concepts of disturbance intensity (DI) and disturbance angle are defined, and a DI evaluation model is established to help detect the difference in sensitivity to solar flares between TEC and VLF signals. Results show the following. (1) The higher the flare level and the longer the duration, the greater the disturbance to the ionosphere. Simultaneously, a phenomenon exists in which the disturbance caused by low-level and long-lasting flares is greater than that caused by high-level flares. (2) VLF phase variation and flare level exhibit a good correlation, and they are also closely related to geographical location and local time. The disturbance degree of a station facing the sun is more evident than that of a station facing away from the sun. The TEC disturbance of stations in the morning (local time) is more obvious than that in the afternoon, and disturbance increases along the direction of Earth’s rotation. (3) When DI is at the same level, the lowest flare level that causes TEC response is higher than the lowest flare level that causes VLF signal response. The disturbance angle of TEC is unevenly distributed within the interval [0°, 90°], and that of VLF signals is more than 85°. The sensitivity of VLF signals to flare response is considerably higher than that of TEC, and the difference between the two even stride across DI level.
topic Disturbance intensity
ionosphere
solar flare
total electron content
very low frequency signals
url https://ieeexplore.ieee.org/document/9400368/
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AT fenggao analysisofglobalionosphericresponsetosolarflaresbasedontotalelectroncontentandverylowfrequencysignals
AT tingzhang analysisofglobalionosphericresponsetosolarflaresbasedontotalelectroncontentandverylowfrequencysignals
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