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Experimental study of the plasmasphere boundary layer using MAGION 5 data (2018)

G. Kotova, M. Verigin, J. Lemaire, V. Pierrard, V. Bezrukikh, J. Smilauer

Wiley-Blackwell

In: Journal of Geophysical Research JGR - Space Physics

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Publication Date: 2018-02-09

Description: The in situ cold plasma measurements onboard MAGION 5 were carried out with very good time resolution and this permitted to analyze thin plasmasphere boundary layer (PBL) near the plasmapause. In this layer the plasma density N is decreasing exponentially with L : N ~exp(( L PP - L )/ W B ), where W B corresponds to the characteristic width of the PBL, the distance in L within which the density varies by a factor of e , L PP is the position of the plasmapause. The density in the boundary layer is inversely proportional to the volume of the unit magnetic flux tube, whereas its width is proportional to the volume of magnetic flux tube. The characteristic width of the plasmasphere boundary layer linearly depends on the time elapsed since the most recent maximum value of K P . Empirical relation for the dependence of the plasmasphere boundary layer width on most recent maximum value of K P and on the lapse time between this maximum and the plasmapause observations is proposed.

Print ISSN: 0148-0227

Topics: Geosciences , Physics

Published by Wiley-Blackwell on behalf of American Geophysical Union (AGU).

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Magnetic storm acceleration of radiation belt electrons observed by the Scintillating Fibre Detector (SFD) onboard EQUATOR-S (1999)

Cyamukungu, M. ; Lippens, C. ; Adams, L. ; [et al.]

Springer

Annales geophysicae 17 (1999), S. 1622-1625

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ISSN: 0992-7689

Keywords: Magnetospheric physics (energetic particles ; trapped ; storms and substorms ; instruments and techniques)

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences , Physics

Notes: Abstract On the basis of the currents induced by electron fluxes in the Scintillating Fibre Detector (SFD) onboard the EQUATOR-S satellite launched on 2 December 1997, an in-situ acceleration of radiation belt electrons is found to possibly contribute to the increase of the flux of electrons with energies greater than 400 keV. The data acquired between 16 December 1997 and 30 April 1998 on the 500–67300 km, 4° inclination EQUATOR-S orbit show that the increase of the energetic electron flux corresponds to the enhanced geomagnetic activity measured through the Dst index.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s00585-999-1622-z

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Contamination in electron observations of the silicon detector onboard Cluster/RAPID/IES instrument in Earth's radiation belts and ring current (2016)

Kronberg, E. ; Rashev, M. ; Daly, P. ; [et al.]

In: Space Weather

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Publication Date: 2020-02-12

Description: Since more than 15 years, the Cluster mission passes through Earth's radiation belts at least once every two days for several hours, measuring the electron intensity at energies from 30 to 400 keV. This data has previously been considered not usable due to contamination caused by penetrating energetic particles (protons at 〉100 keV and electrons at 〉400 keV). In this study, we assess the level of distortion of energetic electron spectra from the RAPID/IES detector, determining the efficiency of its shielding. We base our assessment on the analysis of experimental data and a radiation transport code (Geant4). In simulations, we use the incident particle energy distribution of the AE9/AP9 radiation belt models. We identify the Roederer L-values, L⋆, and energy channels that should be used with caution: at 3≤L⋆≤4, all energy channels (40 – 400 keV) are contaminated by protons (≃230 to 630 keV and 〉600 MeV); at L⋆≃1 and 4–6, the energy channels at 95 – 400 keV are contaminated by high energy electrons (〉400 keV). Comparison of the data with electron and proton observations from RBSP/MagEIS indicates that the subtraction of proton fluxes at energies ≃ 230–630 keV from the IES electron data adequately removes the proton contamination. We demonstrate the usefulness of the corrected data for scientific applications.

Language: English

Type: info:eu-repo/semantics/article

Format: application/pdf

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Estimation of the total oxygen loss from Earth with a semi-empirical model of atmospheric escape (2023)

Alonso Tagle, M. ; Maggiolo, R. ; Gunell, H. ; [et al.]

In: XXVIII General Assembly of the International Union of Geodesy and Geophysics (IUGG)

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Publication Date: 2023-08-29

Description: Understanding atmospheric escape into space for stellar and planetary conditions differing from the current ones on Earth is an ongoing challenge. It helps us to assess the stability of planetary atmospheres, hence their habitability. Over geological time scales, despite the small changes in Earth’s magnetic field magnitude, the solar wind pressure, and EUV radiation from the Sun have evolved significantly, affecting the atmospheric erosion rate. On one hand, the solar wind pressure affects non-thermal processes, and on the other EUV radiation alters Earth’s atmospheric parameters, increasing the ion production rate and the exospheric temperature. Both jointly cause a significant effect on erosion. We developed a semi-empirical model to analyze seven different erosion mechanisms and their dependency on terrestrial and solar parameters, in order to estimate the oxygen escape rate for past conditions. Our model considers variations of the Earth’s magnetic moment, the solar wind pressure, and the solar EUV flux. We discuss the effect of different atmospheric factors and their impact on the oxygen loss for each escape process and provide an estimate of the total amount of oxygen lost by the Earth over the last ~2 billion years. In addition, such a model contributes to identifying the solar and planetary parameters that are critical for the stability of the planet’s atmosphere.

Language: English

Type: info:eu-repo/semantics/conferenceObject

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