Energetic Electron Precipitation Occurrence Rates Determined Using the Syowa East SuperDARN Radar

Bland, Emma; Partamies, Noora; Heino, Erkka; Yukimatu, A. S.; Miyaoka, Hiroshi

doi:10.1029/2018ja026437

Cited by 29 publications

(68 citation statements)

References 51 publications

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“…To perform this estimate, we use the fact that this higher energy precipitation causes enhanced ionisation in the D-region ionosphere, which in turn attenuates high frequency (HF) radiowaves. This attenuation can be detected using Super-DARN HF radars, as previously shown by Bland et al (2019). In this study we build upon this work by using ten SuperDARN radars in Antarctica to estimate the EEP impact area for different types of PsA.…”

mentioning

confidence: 74%

“…SuperDARN is a global network of 36 HF radars designed primarily for studying high-latitude plasma convection (Greenwald et al, 1995;Chisham et al, 2007;Nishitani et al, 2019). Recently, the radars have also been used to detect HF radio attenuation during shortwave fadeout events (Watanabe and Nishitani, 2013;Berngardt et al, 2018;Chakraborty et al, 2018;Fiori et al, 2018), polar cap absorption events (Bland et al, 2018;Chakraborty et al, 2019), and auroral absorption events including PsA (Bland et al, 2019). HF radio attenuation events are identified in the SuperDARN radar data as periods of reduced backscatter power combined with a reduction in the background radio noise.…”

Section: Instrumentationmentioning

confidence: 99%

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D-region impact area of energetic particle precipitation during pulsating aurora

Bland¹,

Tesema²,

Partamies³

2020

Preprint

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Abstract. Ten radars from the Super Dual Auroral Radar Network (SuperDARN) in Antarctica were used to estimate the spatial area over which energetic electron precipitation (EEP) impacts the D-region ionosphere during pulsating aurora (PsA) events. We use an all-sky camera located at Syowa Station to confirm the presence of optical PsA, and then use the SuperDARN radars to detect HF radio attenuation caused by enhanced ionisation in the D-region ionosphere. The HF radio attenuation was identified visually by examining quick-look plots of the background HF radio noise and backscatter power from each radar. The EEP impact area was determined for 74 PsA events. Approximately one third of these events have an EEP impact area that covers at least 12° of magnetic latitude, and three quarters cover at least 4° of magnetic latitude. At the equatorward edge of the auroral oval, 44 % of events have a magnetic local time extent of at least 7 hours, but this reduces to 17 % at the poleward edge. We use these results to estimate the average size of the EEP impact area during PsA, which could be used as a model input for determining the impact of PsA-related EEP on the atmospheric chemistry.

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mentioning

confidence: 74%

Section: Instrumentationmentioning

confidence: 99%

D-region impact area of energetic particle precipitation during pulsating aurora

Bland¹,

Tesema²,

Partamies³

2020

Preprint

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“…Subsequent statistical analysis according to the data of world-wide radar network showed usefulness of this method in the lit time: it allows approve the main influence of the ionosphere near the radar to the absorption; it allows demonstrate the contributions of D-and E-layers to the absorption; it allows estimate the frequency dependence of absorption; it allows localize the region in which the absorption measured [4]. Studies of absorption associated with the corpuscular solar radiation allow demonstrate a good agreement between radio noise 8-20MHz absorption and standard observations by riometers [2,3], allowing to prove the correctness of the technique in these cases too.…”

Section: Introductionmentioning

confidence: 84%

“…Frequency dependence of the detected absorption Traditionally it is believed that the absorption of radio waves vertically propagating in the ionosphere has a power-law frequency dependence [16,17,18,19,2,4,3]:…”

Section: Statistical Characteristics Of Detected Absorptionmentioning

confidence: 99%

“…The use of 8-20MHz radio noise, measured by short-wave radars for the diagnosis of the lower part of the ionosphere, is an intensively developed method [1,2,3,4,5]. The physical processes that cause this effect [4] are close to the physical processes that cause the absorption of the signals scattered from the earth's surface (ground scatter, GS) [6,7], so GS signals and noise level both can be used to study the absorption of radiwaves [5].…”

Section: Introductionmentioning

confidence: 99%

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Noise level forecasts at 8–20 MHz and their use for morphological studies of ionospheric absorption variations at EKB ISTP SB RAS radar

Berngardt¹

2020

Advances in Space Research

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In this paper, a method is described for using 8-20MHz noise absorption effect for realtime detecting radiowave absorption periods. The method is based on two empirical autoregression models of noise dynamics. The first (rough) prediction model is based on radar measurements of daily minimal noise dynamics averaged over 28-days with specially calculated weight coefficients. The second (fine) prediction model uses real-time scaling of rough model. The scaling is based on the comparison of this model with the experimental noise observations during previous 5 days. The models are based on the whole EKB ISTP SB RAS radar dataset (2013)(2014)(2015)(2016)(2017)(2018). The rough model allows one to estimate the boundary beyond which the noise variations can be associated with absorption periods with a high degree of certainty. A joint analysis of simultaneous data on neighboring radar beams and at several frequencies reduces the detection errors, and allows to identify absorption events with a higher degree of confidence. Use of fine model allows to estimate absorption. The technique is validated by frequency dependence of absorption during two-frequency measurements. The found frequency dependence has an average exponent of the order of -1.5, which is in good agreement with the literature data and the data obtained earlier in analysis of solar X-ray flares. The use of the detection technique at EKB radar shows that most probable absorption over absorption events is about -0.65dB. Analysis of absorption of different amplitudes shows that low-intensity absorption events (0..-1.3dB) have slight local time dependence and mostly observed at north directions. For the storng absorption events (stronger than -1.3dB) the local time dynamics correlates well with noise level dynamics, and usually fills the whole radar field-of-view.

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Substorm Activity as a Driver of Energetic Pulsating Aurora

Troyer

Jaynes

Kaeppler

et al. 2022

Preprint

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Energetic Electron Precipitation Occurrence Rates Determined Using the Syowa East SuperDARN Radar

Cited by 29 publications

References 51 publications

D-region impact area of energetic particle precipitation during pulsating aurora

D-region impact area of energetic particle precipitation during pulsating aurora

Noise level forecasts at 8–20 MHz and their use for morphological studies of ionospheric absorption variations at EKB ISTP SB RAS radar

Substorm Activity as a Driver of Energetic Pulsating Aurora

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