Auroral Oval Boundary Dynamics on the Nature of Geomagnetic Storm

Edemskiy, Ilya; Yasyukevich, Yury

doi:10.3390/rs14215486

Cited by 5 publications

(2 citation statements)

References 51 publications

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“…Consequently, the strength of geomagnetic storms directly correlates to the level of threat posed to ground communication and satellite operations. The auroral electrojet (AE) index serves as a globally quantifiable measurement that represents the current flow of auroral-induced geomagnetic disturbances below and within the auroral oval (Frey, 2007;Edemskiy and Yasyukevich, 2022). Additionally, the AE index, introduced by Davis and Sugiura (1966), correlates with the physical processes of energy release in the magnetotail resulting from the interaction between the solar wind and the magnetosphere (Kauristie et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Extreme value theory applied to the auroral electrojet indices

Chen,

Yuan,

Wei

et al. 2024

Earth and Planetary Physics

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By fitting the generalized Pareto distribution to the auroral electrojet (AE) index, negative shape parameters were obtained, suggesting the existence of an upper limit to the AE index.• Understanding the plateau of AE values is crucial for assessing the risks associated with extreme events.• Although values surpassing the upper limit are rare, their existence underscores the need for diligent precautions to mitigate the consequences of such extreme events and for careful consideration in planning and preparedness efforts.

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Section: Introductionmentioning

confidence: 99%

Extreme value theory applied to the auroral electrojet indices

Chen,

Yuan,

Wei

et al. 2024

Earth and Planetary Physics

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“…The geomagnetic activity reaches the maximum around the magnetic latitude of 70 degrees [8]. Auroral oval boundary dynamics is associated with geomagnetic storm intensity [9]. When stronger geomagnetic storms occur, auroras extend frequently equator-ward and increase the appearance of space weather activity [10] [11].…”

Section: Introductionmentioning

confidence: 99%

A Physical Explanation for the Formation of Auroras

Qian¹

2023

JMP

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What mechanism causes the symmetrical distribution of two oval-ring auroras approximately around the geomagnetic poles but uneven brightness distribution of them? To answer this question, we firstly describe the charged particles like electrons or protons emitted from the Sun and the magnetic ions formed in the Earth's atmosphere. Then, the interaction dynamics of two-type particles between electron and ion is given under the non-relativistic limit. Finally, under the relativistic frame, auroras deduced are higher energy density formed by the orthogonal interaction of solar charged particles and geomagnetic ions in the narrow regions centered on the upper geomagnetic poles. The physical nature of ideal oval-ring auroras with uneven brightness distribution is an optical phenomenon that occurs when solar charged particles collide orthogonally with ions and the magnetic axis inclines to the solar radiation. For actual aurora distribution, the impact of multiple factors is discussed. Therefore, the aurora is a natural illustration of an orthogonal collider in the Earth's upper atmosphere.

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Influence of geomagnetic disturbances on scintillations of GLONASS and GPS signals as observed on the Kola Peninsula

Belahovskiy,

Budnikov,

Kalishin

et al. 2023

Solar-Terrestrial Physics

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We have compared effects of geomagnetic disturbances during magnetic storms of various types (CME and CIR) and during an isolated substorm on scintillations of GLONASS and GPS signals, using a Septentrio PolaRx5 receiver installed in Apatity (Murmansk Region, Russia). We analyze observational data for 2021. The magnetic storms of November 3–4, 2021 and October 11–12, 2021 are examined in detail. The November 3–4, 2021 magnetic storm was one of the most powerful in recent years. The analysis shows that the scintillation phase index reaches its highest values during nighttime and evening substorms (σϕ≈1.5–1.8), accompanied by a negative bay in the magnetic field. During magnetic storms, positive bays in the magnetic field, associated with an increase in the eastward electrojet, lead, however, to quite comparable values of the phase scintillation index. An increase in phase scintillations during nighttime and evening disturbances correlates with an increase in the intensity of ULF waves (Pi3/Pc5 pulsations) and with the appearance of aurora arcs. This confirms the important role of ULF waves in forming the auroral arc and in developing ionospheric irregularities. The predominance of the green line in the spectrum of auroras indicates the contribution of disturbances in the ionospheric E layer to the scintillation increase. Pulsating auroras, associated with ionospheric disturbances in the D layer, do not lead to a noticeable increase in phase scintillations. Analysis of ionospheric critical frequencies according to ionosonde data from the Lovozero Hydrometeorological Station indicates the contribution of the sporadic Es layer of the ionosphere to jumps in phase scintillations. The difference between phase scintillation values on GLONASS and GPS satellites during individual disturbances can be as great as 1.5 times, which may be due to different orbits of the satellites. At the same time, the level of GLONASS/GPS scintillations at the L2 frequency is higher than at the L1 frequency. We did not find an increase in the amplitude index of scintillations during the events considered.

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Auroral Oval Boundary Dynamics on the Nature of Geomagnetic Storm

Cited by 5 publications

References 51 publications

Extreme value theory applied to the auroral electrojet indices

Extreme value theory applied to the auroral electrojet indices

A Physical Explanation for the Formation of Auroras

Influence of geomagnetic disturbances on scintillations of GLONASS and GPS signals as observed on the Kola Peninsula

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