Solar type IV burst spectral fine structures

Auraß, H.; Klein, K.-L.; Zlotnik, E. Ya.; Зайцев, В. В.

doi:10.1051/0004-6361:20031249

Cited by 72 publications

(30 citation statements)

References 28 publications

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“…However, stationary fine density structures are required, rather than the transient waves and shock fronts that were mostly considered for simplicity here. Furthermore, Aurass et al (2003) show a good correlation between the inclination of a single zebra stripe to the heliographic observing frequency level in the dynamic spectrogram and the speed of the simultaneously observed projected source motion at this frequency. Besides other effects explaining this feature in terms of the DPR model of Zlotnik et al (2003), one can imagine that the time-dependent inclination of the reflecting regular coronal fine structure may lead both to the frequency drift of zebra lines (due to the change of transmission/reflection coefficient frequency dependence) and to the apparent source motion.…”

Section: The Zebra Patternmentioning

confidence: 70%

Interference patterns in solar radio spectra: high-resolution structural analysis of the corona

Bárta

Karlický

2006

A&A

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Aims. We present a new method for high-resolution structural analysis of the solar corona. Methods. The relationship between the spectral features of various types of solar radio bursts and the physical properties of their sources have been extensively studied by many authors. On the other hand, it is plausible to accept that the spectral properties of the solar radio radiation received on the Earth are -besides the physics of the radio source -influenced by an inter-laying medium that radio waves propagate through. In particular, the regular structures in the solar corona -such as coronal waves, oscillations in shock fronts, the fine structures of coronal loops, streamer current sheets, etc. -might efficiently filter transferred radio radiation just as (broad-band) X-rays are filtered by a periodic atomic structure of crystals; the difference is only in the spatial scale. Using the wave optics methods, we investigate the prospective influence of considered coronal structures on the propagating radio waves originating in an external remote source. Results. Preliminary results have shown that the resulting modelled radio emission may recall the spectra of observed zebra patterns for the simple 1D density structure considered here and for a reasonable set of parameters. Conversely, it is suggested that the spectra of the zebra patterns might be used for an analysis of those coronal structures that made these traces on the radiation by methods similar to those used in crystallography. The possibility of the presence of such regular small scale structures in the solar corona is demonstrated. For completeness, a brief review of contemporary models of the zebra patterns is provided.

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Section: The Zebra Patternmentioning

confidence: 70%

Interference patterns in solar radio spectra: high-resolution structural analysis of the corona

Bárta

Karlický

2006

A&A

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“…Slottje (1972), Aurass & Chernov (1983), Jiřička et al (2001), Aurass et al (2003), Chernov et al (2003), Chen et al (2011), and others.…”

Section: Introductionmentioning

confidence: 99%

Radio continua modulated by waves: Zebra patterns in solar and pulsar radio spectra?

Karlický

2013

A&A

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Aims. We aim to answer the question how waves with plasma density variations affect the radio continua generated by the plasma emission mechanism. Methods. We built a simple semi-empirical model of the radio continuum modulation. Assuming that the waves with density variations are in the source of this radio continuum, we modeled the artificial radio spectrum, which we compared with observed spectra. Results. We show that the waves with density variations modulate the radio continua generated by the plasma emission mechanism. Considering a single slow magnetoacoustic wave, we model the radio spectra, which resemble solar zebra patterns. We show that this modulation generates zebra effects even when the radio continuum is composed of many spiky bursts. Generalizing from one single wave to a wave turbulence we find that the computed radio spectrum is similar to so-called lace bursts. Finally, using the same procedure, but for fast magnetoacoustic waves, we modeled the radio spectrum similar to that observed during the interpulse phase of the radio emission of the Crab Nebula pulsar.

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Section: ¿××çíõ Aeäñìðñåñ òîâêïçððñåñ óçêñðâðôâ (¥±²) ä ïâåðëõñâíõëäðmentioning

confidence: 99%

“…2) âÓÍÑÔÕÐÂâ ÕÇÏÒÇÓÂÕÖÓÂ ËÊÎÖÚÇÐËâ T b AEÑÔÕËÅÂÇÕ ÄÞÔÑÍËØ ÊÐÂÚÇÐËÌ, AEÑ 10 9 ¬ [22]; 3) ÍÑÎËÚÇÔÕÄÑ ÒÑÎÑÔ ÏÇÐâÇÕÔâ ÑÕ ÐÇÔÍÑÎßÍËØ ÇAEËÐËÙ AEÑ ÐÇÔÍÑÎßÍËØ AEÇÔâÕÍÑÄ Ä ÓÂÊÐÞØ ÄÔÒÎÇÔÍÂØ [7,8,14,16, 18,22]; 4) ÓÂÔÔÕÑâÐËÇ ÏÇÉAEÖ ÒÑÎÑÔÂÏË ÔÕÓÖÍÕÖÓÞ ÑÃÞÚÐÑ ÏÐÑÅÑ ÏÇÐßÛÇ ÚÂÔÕÑÕÞ ÓÂAEËÑËÊÎÖÚÇÐËâ [7, 13, 21 ë 25, 27]; 5) ÓÂÔÔÕÑâÐËÇ ÏÇÉAEÖ ÒÑÎÑÔÂÏË Ä ÃÑÎßÛËÐÔÕÄÇ ÔÎÖ-ÚÂÇÄ ÖÄÇÎËÚËÄÂÇÕÔâ Ô ÓÑÔÕÑÏ ÚÂÔÕÑÕÞ [7,12,13,22] [7, 18,20,28,34].…”

Section: ¿××çíõ Aeäñìðñåñ òîâêïçððñåñ óçêñðâðôâ (¥±²) ä ïâåðëõñâíõëäðunclassified

Double plasma resonance аnd its manifestations in radio astronomy

Железняков¹,

Злотник²,

Зайцев³

et al. 2016

Usp. Fiz. Nauk

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¿××ÇÍÕ AEÄÑÌÐÑÅÑ ÒÎÂÊÏÇÐÐÑÅÑ ÓÇÊÑÐÂÐÔÂ (¥±²) Ä ÏÂÅÐËÕÑÂÍÕËÄÐÑÌ ÒÎÂÊÏÇ³ÑÅÎÂÔÐÑ(k k ì ÍÑÏÒÑÐÇÐÕÂ k, ÒÂÓÂÎÎÇÎßÐÂâ ÒÑÎá B). ªÐÕÇÓÄÂÎ ÖÅÎÑÄ a AEÎâ ÔÎÂÃÑ ÊÂÕÖØÂáÜËØ ÒÓÑAEÑÎßÐÞØ ÄÑÎÐ ÏÑÉÇÕ ÃÞÕß ÑÒÓÇAEÇÎÈÐ ÒÖÕÈÏ ÑÃÝÇAEËÐÇÐËâ ÐÇÓÂÄÇÐÔÕÄÂ (9) Ô ÓÇÛÇÐËâÏË AEËÔÒÇÓÔËÑÐÐÑÅÑ ÖÓÂÄÐÇÐËâ (11), (12). ªÊ ÓÇÊÖÎßÕÂÕÂ ÔÎÇAEÖÇÕ, ÚÕÑ AEÎâ ÎáÃÞØ ÄÇÎËÚËÐ l ÖÔÎÑÄËÇ (9) ÖAEÑÄÎÇÕÄÑÓâÇÕÔâ Ä ÖÊÍÑÏ ËÐÕÇÓÄÂÎÇ, ÅAEÇ cos 2 a 5 1. ¦ÔÎË l k . 1) ÄÓÇÏâ ÉËÊÐË ©³ Ä ÓÂÊÐÞØ ÄÔÒÎÇÔÍÂØ ÏÇÐâÇÕÔâ ÑÕ ÐÇÔÍÑÎßÍËØ ÔÇÍÖÐAE AEÑ ÐÇÔÍÑÎßÍËØ AEÇÔâÕÍÑÄ ÏËÐÖÕ [7,8,13,22];2) âÓÍÑÔÕÐÂâ ÕÇÏÒÇÓÂÕÖÓÂ ËÊÎÖÚÇÐËâ T b AEÑÔÕËÅÂÇÕ ÄÞÔÑÍËØ ÊÐÂÚÇÐËÌ, AEÑ 10 9 ¬ [22]; 3) ÍÑÎËÚÇÔÕÄÑ ÒÑÎÑÔ ÏÇÐâÇÕÔâ ÑÕ ÐÇÔÍÑÎßÍËØ ÇAEËÐËÙ AEÑ ÐÇÔÍÑÎßÍËØ AEÇÔâÕÍÑÄ Ä ÓÂÊÐÞØ ÄÔÒÎÇÔÍÂØ [7,8,14,16, 18,22]; 4) ÓÂÔÔÕÑâÐËÇ ÏÇÉAEÖ ÒÑÎÑÔÂÏË ÔÕÓÖÍÕÖÓÞ ÑÃÞÚÐÑ ÏÐÑÅÑ ÏÇÐßÛÇ ÚÂÔÕÑÕÞ ÓÂAEËÑËÊÎÖÚÇÐËâ [7, 13, 21 ë 25, 27]; 5) ÓÂÔÔÕÑâÐËÇ ÏÇÉAEÖ ÒÑÎÑÔÂÏË Ä ÃÑÎßÛËÐÔÕÄÇ ÔÎÖ-ÚÂÇÄ ÖÄÇÎËÚËÄÂÇÕÔâ Ô ÓÑÔÕÑÏ ÚÂÔÕÑÕÞ [7,12,13,22] [7, 18,20,28,34].³ÓÇAEË ÐÂÃÎáAEÇÐËÌ ©³ ÑÔÑÃÑÇ ÊÐÂÚÇÐËÇ ËÏÇáÕ ÓÇ-ÊÖÎßÕÂÕÞ ÐÂÃÎáAEÇÐËÌ ¹ÇÐÂ Ë AEÓ. [7, 18,20,28,32,34] ÐÂ AEÎËÐÇ ÄÑÎÐÞ l 3 ÔÏ ( f 10 ¤¤Ù) AEÎâ ÐÂÃÎáAEÂÇÏÞØ ÒÑÕÑÍÑÄ F $ 100 ÁÐ Ë ÓÂÔÔÕÑâÐËÌ R % 2 ÍÒÍ. ±ÓË ÕÓÂÐÔ×ÑÓÏÂÙËË ÄÑÊÃÖÉAEÂÇÏÞØ ÒÎÂÊÏÇÐÐÞØ ÄÑÎÐ Ä àÎÇÍÕÓÑÏÂÅÐËÕÐÞÇ ÊÂ ÔÚÈÕ ÓàÎÇÇÄÔÍÑÅÑ ÓÂÔÔÇâÐËâ ÐÂ ÚÂÔÕËÙÂØ ÓÂÄÐÑÄÇÔÐÑÌ ÒÎÂÊÏÞ ÄÞÒÑÎÐâÇÕÔâ ÊÂÍÑÐ ÔÑØÓÂ-ÐÇÐËâ àÐÇÓÅËËªÊ ×ÑÓÏÖÎ (56), (57) ÑÒÓÇAEÇÎâÇÕÔâ ÑÃÎÂÔÕß ÐÇÎËÐÇÌÐÑÅÑ ÄÊÂËÏÑAEÇÌÔÕÄËâ àÎÇÍÕÓÑÏÂÅÐËÕÐÑÌ ÄÑÎÐÞ ÚÂÔÕÑÕÑÌ o t Ô ÄÑÊÃÖÉAEÂÇÏÞÏ ÔÒÇÍÕÓÑÏ ÒÎÂÊÏÇÐÐÞØ ÄÑÎÐ: The double plasma resonance effect is a phenomenon in which plasma waves in a magnetized plasma show a sharp increase in instability when the upper hybrid frequency coincides with a cyclotron harmonic frequency. A radiation mechanism associated with this effect provides an explanation of the origin of the "zebra pattern" in radio spectra of the Sun, Jupiter and the Crab pulsar. The diversity of these astronomical objects and the successful interpretation of their spectra in terms of the double plasma resonance effect point to the universal nature of this phenomenon and suggest that one and the same radiation mechanism may operate under a variety of astronomical conditions.

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Solar type IV burst spectral fine structures

Cited by 72 publications

References 28 publications

Interference patterns in solar radio spectra: high-resolution structural analysis of the corona

Interference patterns in solar radio spectra: high-resolution structural analysis of the corona

Radio continua modulated by waves: Zebra patterns in solar and pulsar radio spectra?

Double plasma resonance аnd its manifestations in radio astronomy

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