Investigating energetic electron precipitation through combining ground‐based and balloon observations

Clilverd, Mark A.; Rodger, Craig J.; McCarthy, Michael; Millan, R. M.; Blum, L. W.; Cobbett, Neil; Brundell, James B.; Danskin, D. W.; Halford, A. J.

doi:10.1002/2016ja022812

Cited by 30 publications

(45 citation statements)

References 38 publications

(71 reference statements)

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“…These more energetic photons can propagate further distances in the atmosphere before being eventually absorbed, corresponding to the production of Compton electrons at lower altitudes (see Figure a). Another consequence of this difference has been extensively observed by BARREL: a significant amount of low‐energy photons would be absorbed by the atmosphere before penetrating into the stratosphere, thereby leading to the reduction of X‐ray flux in the energy range below ∼30 keV (e.g., Clilverd et al, ; Woodger et al, ). Furthermore, as shown in Figure b, large quantities of photoelectrons and Compton electrons also can be produced at the altitude of the BARREL payloads.…”

Section: Discussionmentioning

confidence: 99%

On the Effects of Bremsstrahlung Radiation During Energetic Electron Precipitation

Marshall

Fang

et al. 2018

Geophysical Research Letters

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Precipitation of energetic particles into the Earth's atmosphere can significantly change the properties, dynamics, as well as the chemical composition of the upper and middle atmosphere. In this paper, using Monte Carlo models, we simulate, from first principles, the interaction of monoenergetic beams of precipitating electrons with the atmosphere, with particular emphasis on the process of bremsstrahlung radiation and its resultant ionization production and atmospheric effects. The pitch angle dependence of the ionization rate profile has been quantified: the altitude of peak ionization rate depends on the pitch angle by a few kilometers. We also demonstrate that the transport of precipitating electron energy in the form of bremsstrahlung photons leads to ionization at altitudes significantly lower than the direct impact ionization, as low as ∼20 km for 1 MeV precipitating electrons. Moreover, chemical modeling results suggest that the chemical effects in the atmosphere due to bremsstrahlung‐induced ionization production during energetic electron precipitation are likely insignificant.

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Section: Discussionmentioning

confidence: 99%

On the Effects of Bremsstrahlung Radiation During Energetic Electron Precipitation

Marshall

Fang

et al. 2018

Geophysical Research Letters

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“…Precipitating electron fluxes are subject of high variability as observed by many experiments (Clilverd et al, ; Cresswell‐Moorcock et al, ; Mironova et al, ; Nesse Tyssøy et al, ; Woodger et al, ). Here we show the difference between IR from the CMIP6 data set and retrieved from balloon measurements (Makhmutov et al, ).…”

Section: Resultsmentioning

confidence: 99%

“…Information about EEP is usually obtained by satellite instruments, such as National Oceanic and Atmospheric Administration Polar-orbiting Operational Environmental Satellites (e.g., Nesse Tyssøy et al, 2016) or Van Allen Probes (e.g., Shprits et al, 2016). Some information can also be obtained from observation of radio wave propagation (Clilverd et al, 2017). Precipitating energetic electrons also generate X-ray and gamma-ray bremsstrahlung which can be detected by stratospheric balloon experiments (Makhmutov et al, 2016;Millan et al, 2013;Woodger et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…A variety of these processes leads to strong variability of EEP and their dependence on the interplanetary disturbance type, site of observation, local magnetic time, and energy of precipitating electrons. A high EEP interdaily variability has been observed in many experiments (Clilverd et al, 2017;Cresswell-Moorcock et al, 2013;Mironova et al, 2015;Nesse Tyssøy et al, 2016;Woodger et al, 2015). Moreover, the electron energy spectrum used for the IR calculations in the CMIP6 project (Matthes et al, 2017) was limited (to 30 keV to <1 MeV), and the lack of electrons with higher energies can lead to some underestimation of the IR below 1 hPa (altitude less than ∼50 km).…”

Section: Introductionmentioning

confidence: 99%

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Ionization of the Polar Atmosphere by Energetic Electron Precipitation Retrieved From Balloon Measurements

Mironova

Artamonov

Bazilevskaya

et al. 2019

Geophysical Research Letters

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We retrieve ionization rates in the atmosphere caused by energetic electron precipitation from balloon observations in the polar atmosphere and compare them against ionization rates recommended for the Phase 6 of the Coupled Model Intercomparison Project. In our retrieval procedure, we consider the precipitating electrons with energies from about tens of keV to 5 MeV. Our simulations with 1‐D radiative‐convective model with interactive neutral and ion chemistry show that the difference of the Phase 6 of the Coupled Model Intercomparison Project and balloon‐based ionization rate can lead to underestimation of the NOx enhancement by more than 100% and ozone loss up to 25% in the mesosphere. The atmospheric response is different below 50 km due to considering highly energetic electrons, but it is not important because the absolute values of atmospheric impact is tiny. Ionization rates obtained from the balloon observations reveal a high variability.

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“…Very low frequency (VLF) waves propagating subionospherically in the Earth‐ionosphere waveguide respond to changing ionospheric conditions by changes in phase and amplitude. Therefore, observed perturbations to the otherwise constant carrier‐phase of man‐made VLF transmissions are routinely used as a sounding device of the bottom‐side ionosphere (e.g., Clilverd et al, ). Characteristic changes in the number and energy density of charged electrons in the D region ionosphere (approximately 50–90 km altitude) signify the occurrence of events such as precipitation of electrons from the radiation belts due to wave‐particle interactions (e.g., Rodger et al, ), increased ionization due to high X‐ray flux following solar flares (e.g., Thomson et al, ), and electron precipitation during substorm injection events (Clilverd et al, ).…”

Section: Introductionmentioning

confidence: 99%

Demonstrating the Use of a Class of Min‐Max Smoothers for D Region Event Detection in Narrow Band VLF Phase

Lotz

Clilverd

2019

Radio Science

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This paper describes the use of a class of nonlinear smoothers for the identification of interesting phenomena in narrow band very low frequency (VLF) transmission phase caused by perturbation events in the D region of the ionosphere. The LULU smoothers, named for their smoothing of upward (L) and downward (U) peaks in a signal, usually used for image processing tasks, are described, and examples are shown where these operators are used to automatically isolate and identify features in the phase of narrow band transmissions received at high and high‐middle latitudes (Antarctica and Marion Island, respectively). Identification of solar flare events, electromagnetic ion cyclotron wave precipitation, and substorm injection events are demonstrated, showing the potential for this technique to be used for space weather monitoring.

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Investigating energetic electron precipitation through combining ground‐based and balloon observations

Cited by 30 publications

References 38 publications

On the Effects of Bremsstrahlung Radiation During Energetic Electron Precipitation

On the Effects of Bremsstrahlung Radiation During Energetic Electron Precipitation

Ionization of the Polar Atmosphere by Energetic Electron Precipitation Retrieved From Balloon Measurements

Demonstrating the Use of a Class of Min‐Max Smoothers for D Region Event Detection in Narrow Band VLF Phase

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