Propagation Effects on the Cyclotron Maser Mechanism for Solar Microwave Spike Bursts

Kuncic, Zdenka; Robinson, P. A.

doi:10.1017/s132335800002587x

Cited by 3 publications

(1 citation statement)

References 15 publications

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“…It has been thought that there cannot, therefore, be such a plasma surrounding the star or the flare emission would not be able to be seen. However, recent work has discussed various escape possibilities (Kuncic & Robinson 1993), indicating that the radiation may be able to escape from the plasma.…”

Section: Source Of the Quiescent Emissionmentioning

confidence: 99%

Quiescent Non-thermal Radio Emission from Stellar Systems

Storey¹,

Hewitt

1995

Publ. Astron. Soc. Aust.

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Non-thermal radio emission has been detected from dMe stars, RS CVn binaries and W T Tauri stars. Polarisation and intensity measurements of the quiescent (i.e. non-flaring) emission indicate that the emission is gyrosynchrotron emission from mildly relativistic electrons spiralling in a magnetic field. A three-dimensional dipole magnetic field model for the stellar field is presented and the quiescent gyrosynchrotron emission from such a model is calculated and compared with observations. The model can account for many phenomenological features of quiescent emission. Quantitative comparisons of model results with observations indicate that the electron distribution in the emission region may be a magnetic mirroring distribution.

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Section: Source Of the Quiescent Emissionmentioning

confidence: 99%

Quiescent Non-thermal Radio Emission from Stellar Systems

Storey¹,

Hewitt

1995

Publ. Astron. Soc. Aust.

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The critical intensity of Alfvén waves for electron-cyclotron maser to favor the O-mode emission

Zhao

Feng

2015

Physics of Plasmas

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The presence of Alfvén waves (AWs) has been found to significantly affect electron-cyclotron maser (ECM), which is a powerful emission mechanism in astrophysical plasmas. A conventional ECM driven by power-law electrons with a lower-energy cutoff generally prefers X-mode emission to O-mode. In particular, the ECM possibly favors O-mode because it is dependent on the relative intensity of the present AWs, ξ=Bw2/B02, where Bw and B0 are the field strength of AWs and the ambient magnetic field, respectively. This paper, for the first time, quantitatively investigates the critical relative intensity of AWs, above which the ECM becomes to favor the O-mode emission. It is found that the critical intensity depends on velocity distribution function features of energetic electrons, as well as on ambient plasma parameters. In principle, the critical intensity is in the order of ξ ∼ 10−2 for power-law electrons with a lower energy cutoff, when the fundamental wave in X-mode is suppressed. Moreover, the incorporation of the loss cone distribution caused by the magnetic mirror effect can considerably lower the critical intensity of AWs. This study contributes to the understanding of solar type I radio storm emissions, which are dominated by the O-mode.

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The effect of electron beams on cyclotron maser emission excited by lower-energy cutoffs

Zhao

Feng

2016

Physics of Plasmas

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Electron-cyclotron maser (ECM) is one of the most important emission mechanisms in astrophysics and can be excited efficiently by lower-energy cutoffs of power-law electrons. These non-thermal electrons probably propagate as a directed collimated beam along ambient magnetic fields. This paper investigates the ECM, in which the effect of electron beams is emphasized. Results show the dependence of emission properties of the ECM on the beam feature. The maximum growth rate of the extraordinary mode (X2) rapidly decreases as the beam momentum increases, while the growth rate of the ordinary mode (O1) changes slightly. In particular, the ordinary mode can overcome the extraordinary mode and becomes the fastest growth mode once the beam momentum is large enough. This research presents an extension of the conventional studies on ECM driven by lower-energy cutoffs and may be helpful to understand better the emission process of solar type I radio bursts, which are dominated by the ordinary mode emission.

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Propagation Effects on the Cyclotron Maser Mechanism for Solar Microwave Spike Bursts

Cited by 3 publications

References 15 publications

Quiescent Non-thermal Radio Emission from Stellar Systems

Quiescent Non-thermal Radio Emission from Stellar Systems

The critical intensity of Alfvén waves for electron-cyclotron maser to favor the O-mode emission

The effect of electron beams on cyclotron maser emission excited by lower-energy cutoffs

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