49 research outputs found
Radio fiber bursts and fast magnetoacoustic wave trains
We present a model for dm-fiber bursts that is based on assuming fast sausage
magnetoacoustic wave trains that propagate along a dense vertical filament or
current sheet. Eight groups of dm-fiber bursts that were observed during solar
flares were selected and analyzed by the wavelet analysis method. To model
these fiber bursts we built a semi-empirical model. We also did
magnetohydrodynamic simulations of a propagation of the magnetoacoustic wave
train in a vertical and gravitationally stratified current sheet. In the
wavelet spectra of the fiber bursts computed at different radio frequencies we
found the wavelet tadpoles, whose head maxima have the same frequency drift as
the drift of fiber bursts. It indicates that the drift of these fiber bursts
can be explained by the propagating fast sausage magnetoacoustic wave train.
Using new semi-empirical and magnetohydrodynamic models with a simple radio
emission model we generated the artificial radio spectra of the fiber bursts,
which are similar to the observed ones.Comment: 7 pages, 10 figure
Magnetoacoustic waves in the narrowband dm-spikes sources
Aims. A new type of analysis of the narrowband dm-spikes in solar radio radiation is introduced to look for magnetoacoustic waves in their sources.
Methods. The Fourier and wavelet methods were used. For the first time, the tadpole structures in the wavelet spectra of this radio emission were searched for.
Results. Fifteen groups of the narrowband dm-spikes, observed during solar flares, were selected and analyzed by the Fourier and wavelet analysis methods. We found that the mean Fourier spectra of these spikes in frequency space are the powerlaws with a power-law index in the range −1.2 –−1.8. Furthermore, their wavelet spectra based on time series reveal tadpoles at some frequencies, which indicates the presence of magnetoacoustic waves. These waves are interpreted as propagating through a source of the narrowband dm-spikes. It is proposed that the spikes are generated by driven coalescence and fragmentation processes in turbulent reconnection outflow. This interpretation is supported by a simultaneous observation of drifting pulsating structures (DPSs) and spikes. Finally, modeling of the magnetoacoustic waves and tadpoles in the Harris current sheet supports this interpretation
High-frequency slowly drifting structures in solar flares
Radio emission of four solar flares with high-frequency
slowly drifting structures is presented. Three sub-classes of these
structures were recognized. It is shown that the April 15, 2001
X14.4 flare started with the slowly drifting structure associated
with a plasmoid ejection observed by TRACE in the 171 Å line.
The August 18, 1998 event presents an example of the drifting
pulsation structure (DPS) which is well limited in frequency extent
at both sides. A further example of the DPS, but followed by clouds
of the narrowband dm-spikes, was observed during the November 23,
2001 flare. Finally, in the case of the April 12, 2001 flare, the
drifting pulsation-continuum structure was recorded at the same time
as the metric type II radio burst, i.e. in different frequency
ranges. The slowly drifting structures were analyzed and in two cases
their relation to hard X-ray emission was studied. Possible
underlying physical processes are discussed assuming the plasmoid
ejection model of eruptive solar flares
Separation of drifting pulsating structures in a complex radio spectrum of the 2001 April 11 event
Aims. We present new method of separating a complex radio spectrum into single radio bursts. The method is used in the analysis of the 0.8–2.0 GHz radio spectrum of the 2001 April 11 event, which was rich in drifting pulsating structures.
Methods. The method is based on the wavelet analysis technique, which separates different spatial-temporal components (radio bursts) that are difficult to recognize in the original radio spectrum.
Results. We show with this method that the complex radio spectrum observed during the 2001 April 11 event consists of at least four drifting pulsating structures (DPSs). These structures were separated with respect to their different frequency drifts. The DPSs indicate at least four plasmoids that are supposed to be formed in a flaring current sheet
Time scales of the slowly drifting pulsating structure observed during the April 12, 2001 flare
First time scales of high-frequency (500-1500 MHz) slowly drifting
pulsating structures observed during the April 12, 2001 flare by the
Ondřejov (800-4500 MHz) and Potsdam (40-800 MHz) radiospectrographs and by
the 1420 and 610 MHz Trieste radiopolarimeters (with high time resolution (1
ms)) are studied statistically. The Fourier method reveals periods in the range
of 0.9-7.5 s. For shorter periods the power spectra show a power-law
form, especially in the interval of about 0.06-0.2 s, where the power-law index
is in the 1.3-1.6 range. The results are interpreted using the flare model
with plasmoid ejections. For the first time, the multi-scale cascading
reconnection process is included in the interpretation. Corresponding time
scales are estimated analytically. Further, magnetic reconnection in the
bursting regime is simulated in a 2-D MHD model and variations of the
dissipation power and radio radiation measure are computed. Fourier spectra of
these numerical variations are determined and compared with those obtained from
observations
“Drifting tadpoles” in wavelet spectra of decimetric radio emission of fiber bursts
Aims. The solar decimetric radio emission of fiber bursts was investigated searching for
the “drifting tadpole” structures proposed by theoretical studies.
Methods. Characteristic periods with the tadpole pattern were searched for in the radio flux time
series by wavelet analysis methods.
Results. For the first time, we have found drifting tadpoles in the wavelet spectra of the
decimetric radio emission associated with the fiber bursts observed in July 11, 2005.
These tadpoles were detected at all radio frequencies in the 1602-1780 MHz frequency
range. The characteristic period of the wavelet tadpole patterns was found to be 81.4 s
and the frequency drift of the tadpole heads is -6.8 MHz s-1. These tadpoles are
interpreted as a signature of the magnetoacoustic wave train moving along a dense flare
waveguide and their frequency drift as a motion of the wave train modulating the radio
emission produced by the plasma emission mechanism. Using the Aschwanden density model of
the solar atmosphere, only low values of the Alfvén speed and the magnetic field
strength in the loop guiding this wave train were derived which indicates a neutral
current sheet as the guiding structure. The present analysis supports the model of fiber
bursts based on whistler waves
Analysis of solar narrow band dm-spikes observed at 1420 and 2695 MHz
Using both linear and nonlinear methods, narrow band dm-spikes recorded at 1420
and 2695 MHz on June 6, 2000, July 8, 2000, July 12, 2000, July 20, 2000, and
March 28, 2001 were analyzed. In particular their time profiles were studied
statistically. The mean characteristic times of the ascending and of the
decaying parts of their profiles are comparable, even if the dispersion of the
values is very broad. For selected spikes at 1420 MHz a more precise fitting
technique using exponential profiles was applied. While in the decaying part
the exponential trend can be generally found, in the ascending part the
exponential form can be confirmed only in few cases. The ascending and decaying
phase of spikes presumably correspond to the source instability evolution and
the plasma wave absorption. Furthermore, durations and polarization values of
both 1420 and 2695 MHz spikes were determined and compared with the results in
literature. All the analyzed spike events were located near the solar disk
center. The polarization values and their trend in spike groups and the
nearly constant duration suggest that the polarization originates at the
source itself or near it. Selected time series of spikes were tested with
respect to low-dimensional determinism and nonlinearity. We found that spikes
recorded at fixed frequencies are not governed by a linear stochastic process,
as the underlying physical system contains nonlinear signatures.