Occurrence Rates of SuperDARN Ground Scatter Echoes and Electron Density in the Ionosphere

Alexander V. Koustov; Sydney Ullrich; Pavlo V. Ponomarenko; Mehdi Ghalamkarian Nejad; David R. Themens; Robert G. Gillies

doi:10.1029/2022RS007520

Occurrence Rates of SuperDARN Ground Scatter Echoes and Electron Density in the Ionosphere

Alexander V. Koustov^*, Sydney Ullrich, Pavlo V. Ponomarenko, Mehdi Ghalamkarian Nejad, David R. Themens, Robert G. Gillies

^*Corresponding author for this work

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Abstract

Ground scatter (GS) echoes in Super Dual Auroral Radar Network (SuperDARN) observations have been always expected to occur under high-enough electron density in the ionosphere providing sufficient bending of high frequency radio wave paths toward the ground. In this study, we provide direct evidence statistically supporting this notion by comparing the GS occurrence rate for the Rankin Inlet SuperDARN radar and the F region peak electron density (Formula presented.) measured at Resolute Bay by the Canadian Advanced Digital Ionosonde and incoherent scatter radars RISR-N/C. We show that the occurrence rate increases with (Formula presented.) roughly linearly up to about (Formula presented.) and the trend saturates at larger (Formula presented.). One expected consequence of this relationship is correlation in seasonal and solar cycle variations of the GS echo occurrence rate and (Formula presented.). GS occurrence rates for a number of SuperDARN radars at middle latitudes, in the auroral zone and in the polar cap are considered separately for daytime and nighttime. The data indicate that the daytime occurrence rates are maximized in winter and nighttime occurrence rates are maximized in summer for middle latitude and auroral zone radars in the Northern Hemisphere, consistent with the winter anomaly (WA) phenomenon. The effect is most evident in the North American and Japanese sectors, and the quality of WA signatures deteriorates in the European and, especially, in the Australian sectors. The effect does not exist in the South American sector and in the polar caps of both hemispheres.

Original language	English
Article number	e2022RS007520
Number of pages	14
Journal	Radio Science
Volume	57
Issue number	11
Early online date	27 Oct 2022
DOIs	https://doi.org/10.1029/2022RS007520
Publication status	Published - Nov 2022

Bibliographical note

Funding Information:
The SuperDARN data used in this work were collected with the support of the Canadian Space Agency's Geospace Observatory (GO Canada) continuation initiative, the Canada Foundation for Innovation, and the Province of Saskatchewan. The University of Calgary RISR‐C radar is funded by the Canada Foundation for Innovation and is a partnership with the US National Science Foundation and SRI International who also fund RISR‐C radar operation. The research was supported by an NSERC Discovery grant and Data Analysis Grant 424328 from the Canadian Space Agency to A.V.K. The OMNI data were obtained from the GSFC/SPDF OMNIWeb interface at https://omniweb.gsfc.nasa.gov .

Publisher Copyright:
© 2022. American Geophysical Union. All Rights Reserved.

Keywords

CADI ionosonde
electron density
ground scatter occurrence rate
incoherent scatter radars RISR
midlatitude winter anomaly
SuperDARN radars

ASJC Scopus subject areas

Condensed Matter Physics
General Earth and Planetary Sciences
Electrical and Electronic Engineering

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10.1029/2022RS007520

Cite this

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title = "Occurrence Rates of SuperDARN Ground Scatter Echoes and Electron Density in the Ionosphere",

abstract = "Ground scatter (GS) echoes in Super Dual Auroral Radar Network (SuperDARN) observations have been always expected to occur under high-enough electron density in the ionosphere providing sufficient bending of high frequency radio wave paths toward the ground. In this study, we provide direct evidence statistically supporting this notion by comparing the GS occurrence rate for the Rankin Inlet SuperDARN radar and the F region peak electron density (Formula presented.) measured at Resolute Bay by the Canadian Advanced Digital Ionosonde and incoherent scatter radars RISR-N/C. We show that the occurrence rate increases with (Formula presented.) roughly linearly up to about (Formula presented.) and the trend saturates at larger (Formula presented.). One expected consequence of this relationship is correlation in seasonal and solar cycle variations of the GS echo occurrence rate and (Formula presented.). GS occurrence rates for a number of SuperDARN radars at middle latitudes, in the auroral zone and in the polar cap are considered separately for daytime and nighttime. The data indicate that the daytime occurrence rates are maximized in winter and nighttime occurrence rates are maximized in summer for middle latitude and auroral zone radars in the Northern Hemisphere, consistent with the winter anomaly (WA) phenomenon. The effect is most evident in the North American and Japanese sectors, and the quality of WA signatures deteriorates in the European and, especially, in the Australian sectors. The effect does not exist in the South American sector and in the polar caps of both hemispheres.",

keywords = "CADI ionosonde, electron density, ground scatter occurrence rate, incoherent scatter radars RISR, midlatitude winter anomaly, SuperDARN radars",

author = "Koustov, {Alexander V.} and Sydney Ullrich and Ponomarenko, {Pavlo V.} and {Ghalamkarian Nejad}, Mehdi and Themens, {David R.} and Gillies, {Robert G.}",

note = "Funding Information: The SuperDARN data used in this work were collected with the support of the Canadian Space Agency's Geospace Observatory (GO Canada) continuation initiative, the Canada Foundation for Innovation, and the Province of Saskatchewan. The University of Calgary RISR‐C radar is funded by the Canada Foundation for Innovation and is a partnership with the US National Science Foundation and SRI International who also fund RISR‐C radar operation. The research was supported by an NSERC Discovery grant and Data Analysis Grant 424328 from the Canadian Space Agency to A.V.K. The OMNI data were obtained from the GSFC/SPDF OMNIWeb interface at https://omniweb.gsfc.nasa.gov . Publisher Copyright: {\textcopyright} 2022. American Geophysical Union. All Rights Reserved.",

year = "2022",

month = nov,

doi = "10.1029/2022RS007520",

language = "English",

volume = "57",

journal = "Radio Science",

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publisher = "American Geophysical Union",

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T1 - Occurrence Rates of SuperDARN Ground Scatter Echoes and Electron Density in the Ionosphere

AU - Koustov, Alexander V.

AU - Ullrich, Sydney

AU - Ponomarenko, Pavlo V.

AU - Ghalamkarian Nejad, Mehdi

AU - Themens, David R.

AU - Gillies, Robert G.

N1 - Funding Information: The SuperDARN data used in this work were collected with the support of the Canadian Space Agency's Geospace Observatory (GO Canada) continuation initiative, the Canada Foundation for Innovation, and the Province of Saskatchewan. The University of Calgary RISR‐C radar is funded by the Canada Foundation for Innovation and is a partnership with the US National Science Foundation and SRI International who also fund RISR‐C radar operation. The research was supported by an NSERC Discovery grant and Data Analysis Grant 424328 from the Canadian Space Agency to A.V.K. The OMNI data were obtained from the GSFC/SPDF OMNIWeb interface at https://omniweb.gsfc.nasa.gov . Publisher Copyright: © 2022. American Geophysical Union. All Rights Reserved.

PY - 2022/11

Y1 - 2022/11

N2 - Ground scatter (GS) echoes in Super Dual Auroral Radar Network (SuperDARN) observations have been always expected to occur under high-enough electron density in the ionosphere providing sufficient bending of high frequency radio wave paths toward the ground. In this study, we provide direct evidence statistically supporting this notion by comparing the GS occurrence rate for the Rankin Inlet SuperDARN radar and the F region peak electron density (Formula presented.) measured at Resolute Bay by the Canadian Advanced Digital Ionosonde and incoherent scatter radars RISR-N/C. We show that the occurrence rate increases with (Formula presented.) roughly linearly up to about (Formula presented.) and the trend saturates at larger (Formula presented.). One expected consequence of this relationship is correlation in seasonal and solar cycle variations of the GS echo occurrence rate and (Formula presented.). GS occurrence rates for a number of SuperDARN radars at middle latitudes, in the auroral zone and in the polar cap are considered separately for daytime and nighttime. The data indicate that the daytime occurrence rates are maximized in winter and nighttime occurrence rates are maximized in summer for middle latitude and auroral zone radars in the Northern Hemisphere, consistent with the winter anomaly (WA) phenomenon. The effect is most evident in the North American and Japanese sectors, and the quality of WA signatures deteriorates in the European and, especially, in the Australian sectors. The effect does not exist in the South American sector and in the polar caps of both hemispheres.

AB - Ground scatter (GS) echoes in Super Dual Auroral Radar Network (SuperDARN) observations have been always expected to occur under high-enough electron density in the ionosphere providing sufficient bending of high frequency radio wave paths toward the ground. In this study, we provide direct evidence statistically supporting this notion by comparing the GS occurrence rate for the Rankin Inlet SuperDARN radar and the F region peak electron density (Formula presented.) measured at Resolute Bay by the Canadian Advanced Digital Ionosonde and incoherent scatter radars RISR-N/C. We show that the occurrence rate increases with (Formula presented.) roughly linearly up to about (Formula presented.) and the trend saturates at larger (Formula presented.). One expected consequence of this relationship is correlation in seasonal and solar cycle variations of the GS echo occurrence rate and (Formula presented.). GS occurrence rates for a number of SuperDARN radars at middle latitudes, in the auroral zone and in the polar cap are considered separately for daytime and nighttime. The data indicate that the daytime occurrence rates are maximized in winter and nighttime occurrence rates are maximized in summer for middle latitude and auroral zone radars in the Northern Hemisphere, consistent with the winter anomaly (WA) phenomenon. The effect is most evident in the North American and Japanese sectors, and the quality of WA signatures deteriorates in the European and, especially, in the Australian sectors. The effect does not exist in the South American sector and in the polar caps of both hemispheres.

KW - CADI ionosonde

KW - electron density

KW - ground scatter occurrence rate

KW - incoherent scatter radars RISR

KW - midlatitude winter anomaly

KW - SuperDARN radars

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U2 - 10.1029/2022RS007520

DO - 10.1029/2022RS007520

M3 - Article

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VL - 57

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JF - Radio Science

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M1 - e2022RS007520

ER -

Occurrence Rates of SuperDARN Ground Scatter Echoes and Electron Density in the Ionosphere

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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