Multi-scale response of the high-latitude topside ionosphere to geospace forcing

Jaroslav Urbár; Luca Spogli; Antonio Cicone; Lasse Clausen; Yaqi Jin; Alan Wood; Lucilla Alfonsi; Claudio Cesaroni; Daria Kotova; Per Høeg; Wojciech Miloch

doi:10.1016/j.asr.2022.06.045

Multi-scale response of the high-latitude topside ionosphere to geospace forcing

Jaroslav Urbár, Luca Spogli^*, Antonio Cicone, Lasse Clausen, Yaqi Jin, Alan Wood, Lucilla Alfonsi, Claudio Cesaroni, Daria Kotova, Per Høeg, Wojciech Miloch

^*Corresponding author for this work

Electronic, Electrical and Systems Engineering

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Abstract

We investigate the response of the topside ionosphere, auroral and polar sectors, to the forcing of the geospace during September 2017. Specifically, we aim at characterizing such a response in terms of the involved spatial scales and of their intensification during the different auroral and polar cap activity conditions experienced in the selected month, that is characterized by severe geomagnetic storm conditions. For our purposes, we leverage on and compare various in situ plasma density data products provided by the Swarm constellation of the European Space Agency (ESA). The spatio-temporal variability of the involved scales in the plasma density observation is featured through the application of the Fast Iterative Filtering (FIF) signal decomposition technique and, for the first time in the ionospheric field, of a FIF-derived dynamical spectrum called “IMFogram”. The instantaneous time-frequency representation provided through the IMFogram illustrates the time development of the multi-scale processes with spatial and temporal resolutions higher than those obtained with traditional signal processing techniques. To demonstrate this, the IMFogram is tested against Fast Fourier and Continuous Wavelet Transforms. With our fine characterization, we highlight how scale cascading and intensification processes in the plasma density observations follow the ionospheric currents activity, as depicted through the auroral activity and polar cap indices, and through the field-aligned currents data product provided by Swarm.

Original language	English
Journal	Advances in Space Research
Early online date	26 Jun 2022
DOIs	https://doi.org/10.1016/j.asr.2022.06.045
Publication status	E-pub ahead of print - 26 Jun 2022

Bibliographical note

Final Version of Record not yet available as of 12/01/2023.

Funding Information:
Jaroslav Urbar gratefully acknowledges the postdoctoral research fellowship awarded by the PNRA (National Antarctic Research Program) (PNRA 14/00133 - PNRA 14/00110). Antonio Cicone is a member of the Italian “Gruppo Nazionale di Calcolo Scientifico” (GNCS) of the Istituto Nazionale di Alta Matematica “Francesco Severi” (INdAM) and affiliated with the Istituto di Astrofisica e Planetologia Spaziali, INAF, Rome, Italy. This work is part of the activities conducted in the frame of the Swarm Space Weather Variability of Ionospheric Plasma (Swarm VIP) project, that has been funded by the European Space Agency, contract 4000130562/20/I-DT with the title “Swarm+4D Ionosphere”.

Funding Information:
Jaroslav Urbar gratefully acknowledges the postdoctoral research fellowship awarded by the PNRA (National Antarctic Research Program) (PNRA 14/00133 - PNRA 14/00110). Antonio Cicone is a member of the Italian “Gruppo Nazionale di Calcolo Scientifico” (GNCS) of the Istituto Nazionale di Alta Matematica “Francesco Severi” (INdAM) and affiliated with the Istituto di Astrofisica e Planetologia Spaziali, INAF, Rome, Italy. This work is part of the activities conducted in the frame of the Swarm Space Weather Variability of Ionospheric Plasma (Swarm VIP) project, that has been funded by the European Space Agency, contract 4000130562/20/I-DT with the title “Swarm+4D Ionosphere”.

Publisher Copyright:
© 2022 COSPAR

Keywords

Plasma density
Topside ionosphere
Swarm satellite
Time-frequency analysis

ASJC Scopus subject areas

Astronomy and Astrophysics
Aerospace Engineering
Geophysics
General Earth and Planetary Sciences
Space and Planetary Science
Atmospheric Science

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Cite this

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title = "Multi-scale response of the high-latitude topside ionosphere to geospace forcing",

abstract = "We investigate the response of the topside ionosphere, auroral and polar sectors, to the forcing of the geospace during September 2017. Specifically, we aim at characterizing such a response in terms of the involved spatial scales and of their intensification during the different auroral and polar cap activity conditions experienced in the selected month, that is characterized by severe geomagnetic storm conditions. For our purposes, we leverage on and compare various in situ plasma density data products provided by the Swarm constellation of the European Space Agency (ESA). The spatio-temporal variability of the involved scales in the plasma density observation is featured through the application of the Fast Iterative Filtering (FIF) signal decomposition technique and, for the first time in the ionospheric field, of a FIF-derived dynamical spectrum called “IMFogram”. The instantaneous time-frequency representation provided through the IMFogram illustrates the time development of the multi-scale processes with spatial and temporal resolutions higher than those obtained with traditional signal processing techniques. To demonstrate this, the IMFogram is tested against Fast Fourier and Continuous Wavelet Transforms. With our fine characterization, we highlight how scale cascading and intensification processes in the plasma density observations follow the ionospheric currents activity, as depicted through the auroral activity and polar cap indices, and through the field-aligned currents data product provided by Swarm.",

keywords = "Plasma density, Topside ionosphere, Swarm satellite, Time-frequency analysis",

author = "Jaroslav Urb{\'a}r and Luca Spogli and Antonio Cicone and Lasse Clausen and Yaqi Jin and Alan Wood and Lucilla Alfonsi and Claudio Cesaroni and Daria Kotova and Per H{\o}eg and Wojciech Miloch",

note = "Final Version of Record not yet available as of 12/01/2023. Funding Information: Jaroslav Urbar gratefully acknowledges the postdoctoral research fellowship awarded by the PNRA (National Antarctic Research Program) (PNRA 14/00133 - PNRA 14/00110). Antonio Cicone is a member of the Italian “Gruppo Nazionale di Calcolo Scientifico” (GNCS) of the Istituto Nazionale di Alta Matematica “Francesco Severi” (INdAM) and affiliated with the Istituto di Astrofisica e Planetologia Spaziali, INAF, Rome, Italy. This work is part of the activities conducted in the frame of the Swarm Space Weather Variability of Ionospheric Plasma (Swarm VIP) project, that has been funded by the European Space Agency, contract 4000130562/20/I-DT with the title “Swarm+4D Ionosphere”. Funding Information: Jaroslav Urbar gratefully acknowledges the postdoctoral research fellowship awarded by the PNRA (National Antarctic Research Program) (PNRA 14/00133 - PNRA 14/00110). Antonio Cicone is a member of the Italian “Gruppo Nazionale di Calcolo Scientifico” (GNCS) of the Istituto Nazionale di Alta Matematica “Francesco Severi” (INdAM) and affiliated with the Istituto di Astrofisica e Planetologia Spaziali, INAF, Rome, Italy. This work is part of the activities conducted in the frame of the Swarm Space Weather Variability of Ionospheric Plasma (Swarm VIP) project, that has been funded by the European Space Agency, contract 4000130562/20/I-DT with the title “Swarm+4D Ionosphere”. Publisher Copyright: {\textcopyright} 2022 COSPAR",

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AU - Urbár, Jaroslav

AU - Spogli, Luca

AU - Cicone, Antonio

AU - Clausen, Lasse

AU - Jin, Yaqi

AU - Wood, Alan

AU - Alfonsi, Lucilla

AU - Cesaroni, Claudio

AU - Kotova, Daria

AU - Høeg, Per

AU - Miloch, Wojciech

N1 - Final Version of Record not yet available as of 12/01/2023. Funding Information: Jaroslav Urbar gratefully acknowledges the postdoctoral research fellowship awarded by the PNRA (National Antarctic Research Program) (PNRA 14/00133 - PNRA 14/00110). Antonio Cicone is a member of the Italian “Gruppo Nazionale di Calcolo Scientifico” (GNCS) of the Istituto Nazionale di Alta Matematica “Francesco Severi” (INdAM) and affiliated with the Istituto di Astrofisica e Planetologia Spaziali, INAF, Rome, Italy. This work is part of the activities conducted in the frame of the Swarm Space Weather Variability of Ionospheric Plasma (Swarm VIP) project, that has been funded by the European Space Agency, contract 4000130562/20/I-DT with the title “Swarm+4D Ionosphere”. Funding Information: Jaroslav Urbar gratefully acknowledges the postdoctoral research fellowship awarded by the PNRA (National Antarctic Research Program) (PNRA 14/00133 - PNRA 14/00110). Antonio Cicone is a member of the Italian “Gruppo Nazionale di Calcolo Scientifico” (GNCS) of the Istituto Nazionale di Alta Matematica “Francesco Severi” (INdAM) and affiliated with the Istituto di Astrofisica e Planetologia Spaziali, INAF, Rome, Italy. This work is part of the activities conducted in the frame of the Swarm Space Weather Variability of Ionospheric Plasma (Swarm VIP) project, that has been funded by the European Space Agency, contract 4000130562/20/I-DT with the title “Swarm+4D Ionosphere”. Publisher Copyright: © 2022 COSPAR

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N2 - We investigate the response of the topside ionosphere, auroral and polar sectors, to the forcing of the geospace during September 2017. Specifically, we aim at characterizing such a response in terms of the involved spatial scales and of their intensification during the different auroral and polar cap activity conditions experienced in the selected month, that is characterized by severe geomagnetic storm conditions. For our purposes, we leverage on and compare various in situ plasma density data products provided by the Swarm constellation of the European Space Agency (ESA). The spatio-temporal variability of the involved scales in the plasma density observation is featured through the application of the Fast Iterative Filtering (FIF) signal decomposition technique and, for the first time in the ionospheric field, of a FIF-derived dynamical spectrum called “IMFogram”. The instantaneous time-frequency representation provided through the IMFogram illustrates the time development of the multi-scale processes with spatial and temporal resolutions higher than those obtained with traditional signal processing techniques. To demonstrate this, the IMFogram is tested against Fast Fourier and Continuous Wavelet Transforms. With our fine characterization, we highlight how scale cascading and intensification processes in the plasma density observations follow the ionospheric currents activity, as depicted through the auroral activity and polar cap indices, and through the field-aligned currents data product provided by Swarm.

AB - We investigate the response of the topside ionosphere, auroral and polar sectors, to the forcing of the geospace during September 2017. Specifically, we aim at characterizing such a response in terms of the involved spatial scales and of their intensification during the different auroral and polar cap activity conditions experienced in the selected month, that is characterized by severe geomagnetic storm conditions. For our purposes, we leverage on and compare various in situ plasma density data products provided by the Swarm constellation of the European Space Agency (ESA). The spatio-temporal variability of the involved scales in the plasma density observation is featured through the application of the Fast Iterative Filtering (FIF) signal decomposition technique and, for the first time in the ionospheric field, of a FIF-derived dynamical spectrum called “IMFogram”. The instantaneous time-frequency representation provided through the IMFogram illustrates the time development of the multi-scale processes with spatial and temporal resolutions higher than those obtained with traditional signal processing techniques. To demonstrate this, the IMFogram is tested against Fast Fourier and Continuous Wavelet Transforms. With our fine characterization, we highlight how scale cascading and intensification processes in the plasma density observations follow the ionospheric currents activity, as depicted through the auroral activity and polar cap indices, and through the field-aligned currents data product provided by Swarm.

KW - Plasma density

KW - Topside ionosphere

KW - Swarm satellite

KW - Time-frequency analysis

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U2 - 10.1016/j.asr.2022.06.045

DO - 10.1016/j.asr.2022.06.045

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SN - 0273-1177

JO - Advances in Space Research

JF - Advances in Space Research

ER -

Multi-scale response of the high-latitude topside ionosphere to geospace forcing

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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