Low Frequency Radio Astronomy from Above the Ionosphere

The GMRT represents a dramatic improvement in ground-based observing capabilities for low frequency radio astronomy. At sufficiently low frequencies, however, no ground-based facility will be able to produce high resolution images while looking through the ionosphere. A space-based array will be needed to explore the objects and processes which dominate the sky at the lowest radio frequencies. An imaging radio interferometer based on a large number of small, inexpensive satellites would be able to track solar radio bursts associated with coronal mass ejections out to the distance of Earth, determine the frequency and duration of early epochs of nonthermal activity in galaxies, and provide unique information about the interstellar medium.

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Characterization of Selected Solar Radio Bursts Based on Solar Activity Detected by e-CALLISTO (Malaysia)

International Letters of Chemistry Physics and Astronomy ◽

10.18052/www.scipress.com/ilcpa.32.144 ◽

2014 ◽

Vol 32 ◽

pp. 144-154

Author(s):

Zety Sharizat Hamidi ◽

N.N.M. Shariff ◽

C. Monstein

Keyword(s):

Solar Flare ◽

Coronal Mass Ejections ◽

Solar Radio ◽

Low Frequency ◽

Weather Condition ◽

Impulsive Phase ◽

Primary Energy ◽

Radio Bursts ◽

Solar Radio Bursts ◽

Solar Burst

One of the main reasons to study more about the dynamics of solar radio bursts is because solar these bursts can interfere with the Global Positioning System (GPS) and communications systems. More importantly, these bursts are a key to understand the space weather condition. Recent work on the interpretation of the low frequency region of a main solar burst is discussed. Continuum radio bursts are often related to the solar activities such as an indication of the formation of sunspot, impulsive phase of solar flares and Coronal Mass Ejections (CMEs) and their frequencies correspond to the densities supposed to exist in the primary energy release volume. Specifically, solar burst in low frequency play an important role in interpretation of Sun activities. In this work, we have selected few solar bursts that successfully detected by our station at the National Space Centre, Banting Selangor. Our objective is to correlate the solar burst with Sun activities by looking at the main sources that responsibility with the trigger of solar burst. It is found that type II burst is dominant with Coronal Mass Ejections (CMEs), type III burst associated with solar flare, IV burst with the formation of active region and type U burst high solar flare. We believed that this work is a good start to monitor Sun’s activities in Malaysia as equatorial country.

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Solar Radio Bursts at Low Frequencies

Symposium - International Astronomical Union ◽

10.1017/s0074180900234232 ◽

1974 ◽

Vol 57 ◽

pp. 183-200 ◽

Cited By ~ 1

Author(s):

J. Fainberg

Keyword(s):

Solar Radio ◽

Low Frequency ◽

Leading Edge ◽

Emission Region ◽

The Sun ◽

Radio Bursts ◽

Solar Radio Bursts ◽

Low Frequencies ◽

Type Iii ◽

Radio Measurements

Properties of solar radio bursts observed by spacecraft at frequencies below several MHz are reviewed. In this frequency range most of the observed bursts are type III events (associated with particles) but several cases of type II emission (associated with shocks) have been reported. The analyses which lead to emission levels of type III solar bursts out to beyond 1 AU from the Sun also indicate that the low frequency radiation is observed at the harmonic of the emission region plasma frequency. Simultaneous particle and radio measurements imply that the bursts are generated near the leading edge of impulsive streams of solar electrons with energies extending from several hundred keV to several keV. Recent experiments measuring the direction of arrival of the radio emission allow the exciter particles to be tracked along the interplanetary magnetic field from regions near the Sun out to 1 AU.

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Flare-time sudden enhancements of low frequency field strength and associated meter wave solar radio bursts

Solar Physics ◽

10.1007/bf00145741 ◽

1969 ◽

Vol 9 (1) ◽

pp. 198-204 ◽

Cited By ~ 1

Author(s):

S. K. Alurkar ◽

R. V. Bhonsle

Keyword(s):

Field Strength ◽

Solar Radio ◽

Low Frequency ◽

Radio Bursts ◽

Solar Radio Bursts ◽

Frequency Field

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Solar Radio Astronomy at Low Frequencies

Symposium - International Astronomical Union ◽

10.1017/s0074180900169499 ◽

2002 ◽

Vol 199 ◽

pp. 415-425

Author(s):

Monique Pick

Keyword(s):

Radio Telescope ◽

Radio Astronomy ◽

Coronal Mass Ejections ◽

Solar Radio ◽

Electron Beams ◽

Solar Physics ◽

Interplanetary Shocks ◽

Radio Observations ◽

Low Frequencies ◽

Solar Radio Astronomy

This review is concerned to study of sun at frequencies lower than 1.4 GHz. Emphasis is made on results which illustrate the topics in which GMRT could play a major role. Coordinated studies including spectral and imaging radio observations are important for research in solar physics. Joint observations between the Giant Meter Radio Telescope (GMRT) with radio instruments located in the same longitude range are encouraged. This review inludes three distinct topics: Electron beams and radio observations- Radio signatures of Coronal Mass Ejections- Radio signatures of coronal and interplanetary shocks.

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The correlation of solar radio bursts by magnetic activity and cosmic rays

Symposium - International Astronomical Union ◽

10.1017/s0074180900050853 ◽

1959 ◽

Vol 9 ◽

pp. 210-213

Author(s):

A. R. Thompson

Keyword(s):

Cosmic Rays ◽

Radio Astronomy ◽

Solar Radio ◽

Magnetic Activity ◽

Radio Bursts ◽

Type Ii ◽

Frequency Range ◽

Sweep Frequency ◽

Solar Radio Bursts ◽

Auroral Particles

The sweep-frequency equipment at the Harvard Radio Astronomy Station, Fort Davis, Texas, has now been running continuously since 1956 September, recording solar radio activity in the frequency range from 100 to 580 Mc/s. The following contribution describes preliminary investigations of the correlation of the radio data with solar corpuscular emissions. This work was initiated to examine the well-known suggestions that the origins of the type II and type III radio bursts are associated with the ejection of auroral particles and cosmic rays respectively.

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Electron acceleration and radio emission following the early interaction of two coronal mass ejections

Astronomy and Astrophysics ◽

10.1051/0004-6361/202038801 ◽

2020 ◽

Vol 642 ◽

pp. A151

Author(s):

D. E. Morosan ◽

E. Palmerio ◽

J. E. Räsänen ◽

E. K. J. Kilpua ◽

J. Magdalenić ◽

...

Keyword(s):

Magnetic Field ◽

Radio Emission ◽

Coronal Mass Ejections ◽

Solar Radio ◽

Electron Beams ◽

Solar Radio Emission ◽

Radio Bursts ◽

Solar Radio Bursts ◽

Dynamic Spectra

Context. Coronal mass ejections (CMEs) are large eruptions of magnetised plasma from the Sun that are often accompanied by solar radio bursts produced by accelerated electrons. Aims. A powerful source for accelerating electron beams are CME-driven shocks, however, there are other mechanisms capable of accelerating electrons during a CME eruption. So far, studies have relied on the traditional classification of solar radio bursts into five groups (Type I–V) based mainly on their shapes and characteristics in dynamic spectra. Here, we aim to determine the origin of moving radio bursts associated with a CME that do not fit into the present classification of the solar radio emission. Methods. By using radio imaging from the Nançay Radioheliograph, combined with observations from the Solar Dynamics Observatory, Solar and Heliospheric Observatory, and Solar Terrestrial Relations Observatory spacecraft, we investigate the moving radio bursts accompanying two subsequent CMEs on 22 May 2013. We use three-dimensional reconstructions of the two associated CME eruptions to show the possible origin of the observed radio emission. Results. We identified three moving radio bursts at unusually high altitudes in the corona that are located at the northern CME flank and move outwards synchronously with the CME. The radio bursts correspond to fine-structured emission in dynamic spectra with durations of ∼1 s, and they may show forward or reverse frequency drifts. Since the CME expands closely following an earlier CME, a low coronal CME–CME interaction is likely responsible for the observed radio emission. Conclusions. For the first time, we report the existence of new types of short duration bursts, which are signatures of electron beams accelerated at the CME flank. Two subsequent CMEs originating from the same region and propagating in similar directions provide a complex configuration of the ambient magnetic field and favourable conditions for the creation of collapsing magnetic traps. These traps are formed if a CME-driven wave, such as a shock wave, is likely to intersect surrounding magnetic field lines twice. Electrons will thus be further accelerated at the mirror points created at these intersections and eventually escape to produce bursts of plasma emission with forward and reverse drifts.

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