O. N. Savina scite author profile

Abstract. A beam pulsed amplifier mechanism responsible for effective amplification of short very low frequency (VLF) electromagnetic pulses is proposed. Effective amplification near the magnetic equator outside the plasmasphere is considered. A conditional growth rate of short electromagnetic pulses is calculated. Obtained results can explain some important features of the oblique electromagnetic chorus emissions without hiss-like radiation background.

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Features of the radial diffusion of energetic electrons in the middle Jovian magnetosphere

Bespalov

Savina²

2016

Cosmic Res

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Possibility of magnetospheric VLF response to atmospheric infrasonic waves

Bespalov

Savina

2012

Earth Planet Sp

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In this paper, we consider a model of the influence of atmospheric infrasonic waves on VLF magnetospheric whistler wave excitation. This excitation occurs as a result of a succession of processes: a modulation of the plasma density by acoustic-gravity waves in the ionosphere, a reflection of the whistlers by ionosphere modulation, and a modification of whistler wave generation in the magnetospheric resonator. A variation of the magnetospheric resonator Q-factor has an influence on the operation of the plasma magnetospheric maser, where the active substances are radiation belt particles, and the working modes are electromagnetic whistler waves. The magnetospheric maser is an oscillating system which can be responsible for the excitation of self-oscillations. These self-oscillations are frequently characterized by alternating stages of accumulation and precipitation of energetic particles into the ionosphere during a pulse of whistler emissions. Numerical and analytical investigations of the response of self-oscillations to harmonic oscillations of the whistler reflection coefficient shows that even a small modulation rate can significantly change magnetospheric VLF emissions. Our results can explain the causes of the modulation of energetic electron fluxes and whistler wave intensity with a time scale from 10 to 150 s in the day-side magnetosphere. Such quasi-periodic VLF emissions are often observed in the sub-auroral and auroral magnetosphere and have a noticeable effect on the formation of space weather phenomena.

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O. N. Savina

Reflection from and transmission through the ionosphere of VLF electromagnetic waves incident from the mid-latitude magnetosphere

Magnetospheric VLF response to the atmospheric infrasonic waves

An excitation mechanism for discrete chorus elements in the magnetosphere

Features of the radial diffusion of energetic electrons in the middle Jovian magnetosphere

Possibility of magnetospheric VLF response to atmospheric infrasonic waves

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