A&A 434, 1139-1153 (2005)
DOI: 10.1051/0004-6361:20041798
B. P. Dabrowski 1 - P. Rudawy 2 - R. Falewicz 2 - M. Siarkowski 3 - A. J. Kus 1
1 - Torun Centre for Astronomy, Nicolaus Copernicus University,
87-100 Torun, ul. Gagarina 11, Poland
2 -
Astronomical Institute of Wrocaw University,
51-622 Wroc
aw, ul. Kopernika 11, Poland
3 -
Space Research Centre, Polish Academy of Sciences, 51-622 Wrocaw,
ul. Kopernika 11, Poland
Received 5 August 2004 / Accepted 14 December 2004
Abstract
We present here a brief description of thirteen events
of the narrowband solar millisecond radio spike emissions observed
between February 2000 and December 2001. The total observing time
was 1990.4 h, collected during the 357 observing days. The
data were collected with the 15-m radio telescope and fast
radiospectrograph of Torun Observatory, Poland. The dynamic
spectra of the spikes were recorded in the 1352-1490 MHz frequency
band split into 46 frequency channels with temporal resolution
equals to 12 500 measurements per second per channel. The presented
observations have probably the highest time resolution ever
published. Using X-ray, UV and ground based observations we have
analysed the main properties of the active phenomena correlated in
time with the observed spikes. We found that probably all spikes
are emitted as a result of some processes related to the solar
flares. The spikes observed during the solar flares were emitted
from events of various morphologies, various scenarios of
evolution and various configurations of the interacting magnetic
fields. All other emissions of the spikes, not correlated in time
with solar flares, were observed during the slow increases of the
X-ray flux leading to the flares. On the basis of the GOES
database we have estimated that merely 2% of the solar flares are
associated with the radio spikes.
Key words: Sun: radio radiation - Sun: flares - Sun: magnetic fields - Sun: X-rays, gamma rays
Solar radio events with individual emissions shorter than 100 ms were reported for the first time by Dröge & Riemann (1961), Elgarøy (1961) and de Groot (1962), who also introduced their common name, solar radio spikes. Despite more than forty years of investigation, millisecond radio spikes observed in the decimetre wavelength band (dm radio spikes in this paper), often emitted during the impulsive phase solar flares (Bastian et al. 1998), are one of the less understood solar phenomena (Dröge 1967,1977; Bastian et al. 1998).
The emission process of the radio spikes and localization of their sources are still unclear. The emission of the spikes can be related to fine scale elementary processes of the magnetic field annihilation in the energy release region of the solar flares, occurring on very short time scales and on very small spatial scales (Benz 1985; Messmer & Benz 2000) or/and to the "secondary'' fragmentation of the magnetic fields directly in the radio source (Aschwanden & Güdel 1992; Fleishman & Melnikov 1999).
The spatial structure and temporal changes of the sources of the radio spikes are unattainable by contemporary instruments working in visual, UV and X-ray domains. Fortunately, numerous radio instruments now have much higher temporal resolution. For this reason a complex interrelated analysis of the radio observations of the solar spikes could provide much valuable information concerning small- and short-scale physical processes as well as the main properties of the regions involved (Aschwanden & Benz 1997; Robinson 1991; Benz et al. 2001).
In this paper we present a review of the thirteen events of the
emission of numerous dm solar radio spikes, recorded by one of us
(BPD) with the 15-m radio telescope and fast radiospectrograph of
Torun Observatory, Poland between March 15, 2000 and October
30, 2001 (Dabrowski et al. 2002,2003). The total
observing time was 1990.4 h, collected during the 357
observing days between February 2000 and December 2001. The
observations were made in the 1352-1490 MHz frequency band split
into 46 channels, with high time resolution (12 500 measurements
per second and per channel) and moderate frequency resolution
(3 MHz per channel). Using X-ray data collected by the Yohkoh Soft X-ray Telescope (SXT) (Tsuneta et al. 1991) and Hard
X-ray Telescope (HXT) (Kosugi et al. 1991), GOES flux monitor
and Interball/RF-15I photometer (Sylwester et al. 2000), UV
images taken with the Transition Region and Coronal Explorer (TRACE) (Wolfson et al. 1997) as well as EIT telescope on board the
SOHO satellite (Delaboudinière et al. 1995) and ground based
observations made in H
hydrogen line in Wroc
aw
Observatory, Poland, we have identified the most likely active
solar phenomena related to some spikes and we have investigated
the main morphological properties and evolution of these active
phenomena.
The dm radio spikes are short living individual emissions of electromagnetic waves (usually of duration not longer than 100 ms), recorded in very narrow frequency bands above an arbitrary chosen limit of the order of 1 GHz (Dröge 1977). They occur often during the DCIM (decimetre, complex, highly structured radio emission) events. As a rule they appear in multi-element groups, typically up to many thousands of individual events each (Benz 1985; Bastian et al. 1998). Sometimes can one divide the groups of events into subgroups or "chains'' of spikes (Güdel & Benz 1988). The dm radio spikes can be observed with high time resolution due to their very high flux densities (of the order of 100 solar flux units, 1 sfu = 10-19 erg s-1 cm-2 Hz-1) and very high brightness temperature, greater than 1013-1015 K (Bárta & Karlický 2001; Benz 2002; Kuznetsov & Vlasov 2003). This high brightness temperature indicates coherent mechanism of emission (Bastian et al. 1998).
The relative bandwidths of the radio spikes are of the order of a few percent and can vary significantly both from one event to another and within the same event (Fleishman & Melnikov 1999; Benz 1986). Also Csillaghy & Benz (1993) analysed two emissions of the spikes recorded in 1.08-1.6 GHz and 1.0-1.35 GHz bands and they found the average relative bandwidths of the spikes of 1.3% and 4.1%, respectively. Messmer & Benz (2000) found for radio spikes observed in the 0.87-1 GHz band a mean relative bandwidth equal to around 0.8% and the smallest relative bandwidth of the individual spike equal to 0.17% only.
The time profiles of the spike emission was studied first by Güdel & Benz (1990). In particular they found the Gaussian shape of the rise phase and the exponential decay phase, which was later interpreted as evidence of quasi-linear relaxation (Fleishman & Arzner 2000). 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 (Mészárosová et al. 2003).
The dynamical radio-spectra of the spikes show their very fast drifts in frequency, with a wide scatter of the drift rates over positive and negative values (the negative drift is defined as a change of the observed frequency from higher to lower) but usually the negative drifts dominate. The drifts rates of the dm radio spikes lie between -1 and -4 GHz per second at 770 MHz (Güdel & Benz 1990), while their absolute drift rates lie between 2.2 to 4.3 GHz per second in 2.7-3.8 GHz band (Wang et al. 2002). However, observed drifts of the emission frequency of the individual spikes or groups of spikes can be construed not only as a result of the motion of the exciting factor through the plasma but also as a local change of the physical parameters of the emitting plasma. Millisecond radio spikes can have an arbitrary polarisation degree, ranging from 0% to 100%. Usually the spikes originating near the solar limb are weakly polarized, those from the disk centre are highly polarized (Güdel & Zlobec 1991).
The emission of radio spikes is often correlated in time with the hard X-ray (HXR) emission during the impulsive phase of the solar flares (Benz & Kane 1986; Benz et al. 2001), however observed time delays of spike groups after the HXR peaks are of the order of a few seconds (Aschwanden & Güdel 1992). The decimetre radio spikes have the highest association rate with flares (95%) of all coherent radio emissions. On the contrary, only 2% of all hard X-ray events are associated with dm radio spikes (Aschwanden & Güdel 1992). Unfortunately, due to an insufficient temporal resolution of the presently available X-ray observations, it is not possible to check the temporal correlation of the individual radio spikes with short-term changes of the HXR flux.
The current data about the radio spikes are in favor of the idea of (at least) two different kinds of spike event: one class is composed of spike clusters originating in a post-flare phase and located far away from the main flare location (Benz et al. 2002) and the other is composed of the clusters appeared in the main flare phase and well correlated with other nonthermal flare emission: HXR (Aschwanden & Güdel 1992) and microwave gyrosynchrotron emission (Fleishman et al. 2003). The sources of the first class of events, studied by Benz et al. (2002), are located far from strong magnetic field sites, while those from the second class (Fleishman et al. 2003) are related to the flares with the relatively strongest magnetic field.
Theoretical models of radio spike emission are based mainly on plasma emission and acceleration processes (Kuijpers et al. 1981; Tajima et al. 1990; Wentzel 1991; Bárta & Karlický 2001) or on electron-cyclotron maser emission (Holman et al. 1980; Melrose & Dulk 1982; Sharma & Vlahos 1984; Winglee et al. 1988; Aschwanden 1990; Fleishman & Yastrebov 1994; Fleishman & Melnikov 1999). Spikes were interpreted also as radio emission of electrons accelerated in MHD cascading waves generated in plasma outflows from the magnetic reconnection region (Karlický et al. 1996). According to the most reliable estimations, the size of the sources of the individual radio spikes should be smaller than 200 km, taking into account a coherent mechanism of emission (Bastian et al. 1998).
The observations of the radio spikes used herein have been collected with the 15 m radio telescope of Torun Centre for Astronomy, Nicolaus Copernicus University in Torun, Poland. The telescope has a solid parabolic dish supported on an equatorial mount and is used with the prime focus optics. The half width of the beam at 1420 MHz is equal to 50 min of an arc. The receiver is uncooled; the flux density equivalent system temperature was around 2850 Jy.
During the observations of the dm spikes the 15 m telescope
was connected to the fast radiospectrograph Pulsar Machine II
(PSPM II) (Cadwell 1997). PSPM II is routinely used for
pulsar observations with the 32-m radiotelescope of the
Torun Observatory. PSPM II has a
MHz (polarization
channels
filter width) filter-bank built for
observations of the pulsars at frequencies above 1 GHz with very
high temporal resolution and precise timing. For technical reasons
the polarization of the emission of the dm spikes was not
measured.
Dynamical radiospectrograms of the spikes were recorded in the
1352-1490 MHz frequency band split into 46 channels each 3 MHz
wide. The time resolution of the collected data is equal to 80 s, and all channels were scanned 12 500 times per
second. The presented observations of the radio spikes in the dm
band probably have the highest time resolution ever obtained
(Jin et al. 1986; Stähli & Magun 1986; Allaart et al. 1990;
Gary et al. 1991). Up to June 2000 we have observed the Sun
simultaneously in the 1352-1490 MHz band and at 327 MHz with the
10 MHz bandwidth in total power mode. We call this the 327 MHz
band. After June 2000 we made observations in the 1352-1490 MHz
band only.
The radio data were processed in order to make the sensitivities of the individual channels homogeneous but were not calibrated in absolute flux units. For subsequent automatic numerical evaluation of the main properties of the individual spikes we have freely adopted a working definition of the spike as a short-lasting increase of the flux with the peak more than 3 times above the level of the local background. Each individual radio spike was fitted with a two-dimensional elliptical Gaussian (using a non-linear least square method) and the main descriptive parameters were measured at the intensity level equal to half of the maximum: duration, bandwidth and slope (i.e. a rate of the drift in frequencies) (see Fig. 1). For reliable comparison of the radio data with other observations as well as for precise determination of the beginning, maximum and end of the radio event, we used the mean flux averaged over all channels. Evaluation of the main properties of the individual spikes was made using the data with intentionally limited temporal resolution (using an averaging filter of an arbitrarily chosen width from 0.8 up to 4 ms, depending on the overall properties of the evaluated event).
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Figure 1: Definition of the main morphological parameters of the individual dm radio spike evaluated using automatic non-linear fitting of the spike's dynamical radiospectrogram with a two-dimensional elliptical Gaussian. |
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Thirteen events of narrowband solar millisecond radio spikes were
observed between March 15, 2000 and October 30, 2001. Using X-ray
data collected with instruments installed on board the Yohkoh, GOES and Interball satellites, UV images
taken with the TRACE and SOHO/EIT telescopes and
ground based observations made in the H
hydrogen line we
identified the most likely active solar phenomena related to
observed spikes. Unfortunately, the GOES, Interball
and radio data used by us do not have spatial resolution. Yohkoh, TRACE and SOHO data have quiet good space
resolution but relatively low time resolution. For this reason the
only usable criterion of the identification of the spikes' source
was temporal correlation of some solar active phenomenon and the
recording of the radio spikes. We are not able to prove
undoubtedly the correctness of such a selection made in any
particular case, while some co-temporal, but rather faint and
undetected active processes on the Sun could also emit spikes.
We have paid special attention to precluding any artificial radio signals of a terrestrial origin. In 2000 the observations were carried out also at 327 MHz. All radio events observed in 2000 up to June 21st and presented in this paper were observed simultaneously in both, very different, bands. The majority of the events were observed at other radio observatories, using other frequency bands. Only two presented events were recorded solely in Torun.
We have evaluated the main observational parameters of the 5328 individual dm radio spikes. The shortest observed spike lasted 0.0026 s only, the longest one 0.284 s. The distribution of durations is right-skewed with a skewness of 1.64, its median 0.029 s; the mean is equal to 0.036 s. 5165 spikes (97%) were shorter than 0.1 s, fulfilling the commonly accepted upper limit on spike duration.
Other basic observational parameters of the spikes (drifts, widths and relative widths) shorter than 100 ms for each observed event are presented in Tables 1 and 2. The distributions of almost all presented parameters are right-skewed, only a few are nearly Gaussian or left-skewed. In the tables we present values of mean, median and skewness of the distribution of all parameters but we do not present the histograms.
Table 1: Main observational properties of the dm radio spikes shorter than 100 ms, observed between February 2000 and December 2001 with the 15-m radio telescope and fast radiospectrograph of Torun Observatory. The drifts in frequency were calculated for spikes with inclined dynamic spectra only, vertical spectra were considered as having non-measurable drifts.
Table 2: Main properties of the selected dm radio spikes shorter than 100 ms observed in three events on 11 July 2000. The drifts in frequency were calculated for spikes with inclined dynamic spectra only, vertical spectra were considered as having non-measurable drifts.
Table 3: Main properties of the dm radio spikes with and without internal structure, shorter than 100 ms, observed between February 2000 and December 2001 with the 15-m radio telescope and fast radiospectrograph of Torun Observatory.
The presented durations of the spikes are much longer than the mean duration of the spikes equal to 10 ms, estimated for the same frequency band by Güdel & Benz (1990), and also are longer than the 10 ms mean duration of the spikes observed by Mészárosová et al. (2003). The reason for the difference is not clear, but it cannot be attributed to the observational setup used, for example to the limited temporal resolution of the collected data.
A part of the observed spikes, called by us "spikes without internal structure'', have a simple form of a single increase of the radio flux, limited in time and frequency (see Fig. 22). We have also recorded numerous short, spike-like dm radio emissions showing a well outlined subtle internal structure, consisting of a few local, internal maxima (see Fig. 19). We will refer them arbitrary as "spikes with internal structure''. For single-frequency instruments or instruments with a limited temporal resolution both kinds of spikes look identical. If the spikes with internal structure are genuine individual spikes with real internal subtle structure or if they are in fact very short-lasting chains of tightly packed spikes with very fast drifts in frequencies should be addressed by future investigations. The main properties of the dm radio spikes with and without internal structure and shorter than 100 ms, observed by us between February 2000 and December 2001, are presented in Table 3.
We classified five radio events (observed on 21 May 2000, 11 July 2000 and 22 March 2001) as ones with spikes without the internal structure only. These events contained 1720 spikes. The distribution of the durations of the 1699 spikes shorter than 0.1 s is right-skewed with skewness equal to 1.86, its median is equal to 0.024 s and its mean is equal to 0.029 s. Four radio events (observed on 15 March 2000, 17 May 2000, 23 April 2001 and 30 October 2001) contained 1895 spikes with internal structure, with 1837 spikes shorter than 0.1 s. The distribution of their durations is close to Gaussian (skewness equal to 0.12) with the median equal to 0.047 s and the mean equal to 0.046 s. The time scale of the internal subtle structures is roughly one order of magnitude shorter. The relative widths in frequency of these emissions are similar to the parameters of the "classical'' spikes without internal structure.
The drifts of the spikes with internal structure are distinctly slower than ones without structure. The distribution of the negative drifts of the 381 spikes without structure shorter than 0.1 s is right-skewed with skewness equal to 1.7, its mean is equal to 1089 MHz/s and its median is equal to 762 MHz/s. The distribution of the positive drifts of the 236 spikes without structure shorter than 0.1 s is right-skewed with skewness equal to 2.3, its mean is equal to 1460 MHz/s and its median is equal to 1113 MHz/s. The distribution of the negative drifts of the 1462 spikes with internal structure shorter than 0.1 s is right-skewed with skewness equal to 9.1, its mean is equal to 467 MHz/s and its median is equal to 321 MHz/s. The distribution of the positive drifts of the 136 spikes with structure and shorter than 0.1 s is right-skewed with skewness equal to 6.1, its mean is equal to 942 MHz/s and its median is equal to 604 MHz/s.
We have found that in a framework of the single radio event all emitted dm radio spikes are rather similar. Nevertheless, both types of spikes (with or without internal structure) can be emitted in the same event. Each spike has its own positive (i.e. from low to high) or negative (i.e. from high to low) drift in frequency of various speeds (from tens of MHz per second up to greater than the highest measurable with our instrument, equal to 37.5 GHz per second). Assuming a plasma emission mechanism as a source of the observed spikes, the positive drift in frequency can be interpreted as a motion of the exciter downward (or local increase of the plasma density), while the negative drift can be caused by upward motion (or local decrease of the plasma density).
On the dynamic radiospectrograms of the investigated events we have noticed two kinds of well-outlined complex structures formed by numerous individual spikes: well-known chains of spikes and distinctly different structures, "columns''. The chains of spikes, observed already e.g. by Güdel & Benz (1988), are formed by tight groups of spikes with their emission band drifting in frequency (i.e. chains with drift) (see Fig. 17) or emitted in a constant band (chains without drift) (see Fig. 11). The columns of the spikes are formed by numerous individual spikes, recorded over a very short time interval on various frequency of the whole observed band (see Fig. 7). In the column, each individual spike can show positive (i.e. from low to high) or negative (i.e. from high to low) drift in frequency. The durations of the chains of the spikes observed by us vary from 100 ms up to 500 ms while the durations of the columns were not longer than 200 ms.
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Figure 2: GOES (1-8 Å), HXT/L (14-23 keV), HTX/M1 (23-33 keV), Interball (30-60 keV) and radio (1352-1490 MHz) fluxes recorded during the investigated radio events with dm radio spikes. The time range of the dm radio spike emission is outlined by vertical dotted lines. The y-axis is scaled in relative units. |
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We have detected thirteen radio events with eighteen emissions of groups of dm radio spikes. Using the Yohkoh/HXT flux curves made in L and M1 channels, we have found that eleven groups of spikes were emitted during increases of the X-ray flux or during the impulsive phases of the solar flares, two groups were emitted during the peaks of the flares and five groups were observed during the gradual phases of the flares (according to the GOES flux curves for 1-8 Å band). The detailed descriptions of the relevant solar events are given below.
The dm radio spikes were recorded between 12:20:06 UT and
12:21:08 UT (see Fig. 3) during the DCIM radio
event (complex, highly structured emission between 300 and
3000 MHz), observed by us since 12:19:50 UT (it started before the
beginning of our observations). The event peaked at 12:20:50 UT
and ended at 12:26:20 UT. It was observed by us simultaneously in
the 1352-1490 MHz and 327 MHz bands. We have recorded both types
of spikes: with and without internal structure. The spikes
occurred during the impulsive phase of the C5 class solar flare in
the NOAA 8906 active region (S18W19) of the magnetic type
.
The flare started at 12:13 UT, reached a
maximum at about 12:29 UT and ended at 12:55 UT, according to the
GOES classification. A weakly marked plateau on the GOES flux curve preceded the impulsive phase of the flare (see
Fig. 2). The HXT telescope on board the Yohkoh telescope recorded the emission of the flare in channel L
(14-23 keV), which peaked at 12:20 UT, six seconds before the
beginning of the emission of the spikes. Such a delay between the
peak of the high energy hard X-ray emission and the beginning of
the emission of the radio spikes is a typical phenomenon
(Aschwanden & Güdel 1992). The maximum of the total radio flux was
observed about 50 s after the maximum of the HXR emission.
The flare was caused very likely by the Y- or I-type interaction
of the loops in an arcade of loops (Sakai & de Jager 1996), well
visible on the images taken with the SXT telescope (see
Fig. 4). The maximum of the temperature of the
plasma T=8 MK was recorded at 12:25 UT, while the maximum
of the emission measure
cm-3
occurred four minutes later (both values were evaluated using GOES data).
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Figure 4: Image of the NOAA 8906 active region taken with SXT/Al12 on 15 March 2000 at 12:18:37 UT, one and a half minutes before the emission of the dm radio spikes. |
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The radio DCIM event was observed between 13:10:28 UT and
13:13:45 UT. The first group of dm radio spikes was recorded
between 13:10:37 UT and 13:10:50 UT and the second one between
13:11:17 UT and 13:11:34 UT (see Fig. 7). On the
dynamic radiospectrogram the spikes forms columns, the individual
spikes have no internal structure. Both groups of spikes occurred
at the beginning and at the end of the impulsive phase of the M1.0
solar flare, respectively (see Fig. 2). The M1.0
solar flare started at 13:12 UT, peaked at 13:19 UT and end at
13:34 UT. It was observed in the NOAA 9390 active region (N14E60)
of magnetic type .
The start of the impulsive phase of the
flare was marked by the temporal increase of the hard X-ray flux
recorded with the HXT/L telescope. The GOES X-ray light
curve of the flare shows a plateau following the impulsive phase.
The maximum of the temperature of the plasma T=16.1 MK was
observed at 13:17 UT, while the maximum of the emission measure
cm-3 was recorded at 13:28 UT
(both values are evaluated using GOES data). During the
maximum of the flare, the TRACE telescope recorded bright
loops and bright emission kernels (in the 171 Å band) but we
have not found any bulk mass motion or severe rebuilding of the
magnetic configuration (see Fig. 8).
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Figure 6: Image of the NOAA 9042 active region taken with SXT/Al12 on 21 June 2000 at 09:46:04 UT. |
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Figure 7: Dynamic radiospectrogram of the dm radio spikes recorded on 22 March 2001, beginning at 13:11:15 UT. On the spectra one can recognise columns of spikes. The individual spikes have no internal structure. |
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The radio DCIM event started at 10:08:30 UT and ended at
10:21:50 UT. The first group of dm radio spikes was recorded
between 10:09:53 UT and 10:10:03 UT, the second one between
10:14:45 UT and 10:15:05 UT (see Fig. 9). We
have recorded both types of spikes: with and without internal
structure. The first group of spikes, well correlated in time with
a short emission of hard X-rays, occurred at the beginning of the
minor increase of the X-ray flux, followed by the plateau on the
X-ray light curve of the C9.1 solar flare (see
Fig. 2). The flare occurred in the NOAA 9433
active region (N17E26) of magnetic type
;
it started at 10:06 UT, peaked
at 10:18 UT and ended at 10:23 UT. The second group of spikes was
recorded at the beginning of the main impulsive phase of the flare
which was signalled also by the second increase of the hard X-ray
flux. The same flare was observed as an SF H
class flare
between 10:10 UT and 10:29 UT. The maximum of the temperature of
the plasma T=14.6 MK was recorded at 10:17 UT, while the
maximum of the emission measure
cm-3 at 10:21 UT (both values are evaluated using GOES
data). Both groups of spikes occurred simultaneously with the flow
of matter along arcades of the loops (see
Fig. 10).
The dm radio spikes were recorded between 14:09:55 UT and
14:10:35 UT (see Fig. 11), during the radio
event observed from 14:09:34 UT, which peaked at 14:10:08 UT and
ended at 14:11:08 UT. The event was observed by us simultaneously
in the 1352-1490 MHz band and in the 327 MHz band, where we
recorded a noise storm. While the fluxes of the individual
spikes were very low and the spikes were very short in time, we
are not able to make reliable quantitative measurements of their
main properties, except the mean duration of 0.05 s, and a
bandwidth about 7 MHz. Some spikes formed the separate chains of
the spikes. The spikes were observed during a small increase of
the X-ray flux (B7 GOES class), observed in X-rays between
14:09 UT and 14:26 UT, mainly with the hard channel (0.5-4 Å),
but also in the soft channel (1-8 Å) of the GOES satellite
(see Fig. 2). This increase of the X-ray flux
was caused by an I-type interaction of two loops, well recorded
by the SXT telescope in the NOAA 8970 active region (S15E10) of
the magnetic type
(see
Fig. 12). The beginning of the emission of the
radio spikes apparently occurred during the energy release in
the system of interacting loops. The maximum of the temperature
of the plasma T=9 MK occurred at 14:11 UT, while the
maximum of the emission measure
cm-3 was observed two minutes later (the values are
evaluated using SXT data).
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Figure 8: Image of the NOAA 9390 active region taken with TRACE (171 Å) telescope on 22 March 2001 at 13:13:23 UT ( left panel) and at 13:16:23 UT ( right panel). The arrows points to the loop gradually filled by the hot plasma. |
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Figure 10: Image of the NOAA 9433 active region taken with TRACE (171 Å) on 23 April 2001 at 10:20:08 UT. The arrows show the directions of the plasma motion. |
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Figure 11: Dynamic radiospectrogram of the dm radio spikes recorded on 26 April 2000, beginning at 14:10:05 UT. Some spikes formed separate chains. |
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Figure 12: Image of the NOAA 8970 active region taken with SXT/AlMg telescope on 26 April 2000 at 14:18:08 UT. |
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The dm radio spikes occurred in two groups, separated in time by
nearly 79 s (see Fig. 13). The first group
of spikes was recorded between 15:42:21 UT and 15:42:26 UT, the
second one was recorded between 15:43:45 UT and 15:43:52 UT. The
whole radio event, which started at 15:41:40 UT, consists of a few
local maxima with the highest one exactly co-temporal with the
first group of dm radio spikes mentioned before. It was observed
by us simultaneously in the 1352-1490 MHz band and in the 327 MHz
band, where we recorded the noise storm. The spikes were well
distinguishable from the recorded radio background. We have
recorded both kinds of the spikes: with and without internal
structure. The radio spikes were observed during the small GOES X-ray event (C2.2 GOES class) (the first group of
spikes occurred at the beginning of the X-ray flux rise) in the
NOAA 8999 active region (N20E20) of magnetic type
(see
Fig. 2). The X-ray event was associated with an
SF class H
flare reported between 15:44 UT and 15:56 UT.
The images of the active region taken with the TRACE
telescope in the 195 Å band shows two separate regions of
interaction of the short loops and an ejection of the plasma from
the northern part of the active region, which was co-temporal with
the emission of the dm radio spikes (see Fig. 14).
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Figure 13: Dynamic radiospectrogram of the dm radio spikes recorded on 17 May 2000, beginning at 15:43:45 UT. |
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The whole radio event started at 09:39:14 UT, reached maximum at
09:39:33 UT and ended at 09:40:10 UT. It was observed by us
simultaneously in the 1352-1490 MHz and 327 MHz bands. During this
event we recorded two groups of dm radio spikes: the first one
started at 09:39:26 UT and ended at 09:39:31 UT, the second one
started at 09:39:44 UT and ended 09:39:45 UT (see
Fig. 15). The spikes have no the internal
structure. Between the observations of both groups of spikes we
also recorded a radio emission with the dynamic radiospectrograms
similar to the "glued'' spikes. The radio spikes were observed
during the more than 1.5 h very slow increase of the X-ray
signal (the GOES signal was at the C6 level during the
emission of the dm radio spikes), which peaked at about 10:25 UT
at the C8.2 level as an SF class solar flare in the NOAA 8996
active region (S18W47) of magnetic type
(see
Fig. 2). We have not found any other
manifestations of solar activity which can be combined with the
spikes.
The radio spikes were observed from 10:37:44 UT to 10:38:04 UT,
during the DCIM radio event observed by us from 10:30:20 UT to
10:50:00 UT (see Figs. 16 and 17) simultaneously in 1352-1490 MHz and
327 MHz bands. The recorded radio flux consists of two components:
quiet rise and fall emission overlaid with three short-lasting
peaks. The emission of the spikes occurred at the same time as the
second, but not the highest, peak of the radio flux (see
Fig. 2). Numerous recorded spikes have internal
structure but other have not. Some spikes were aggregated in
chains. The spikes occurred during the maximum of the C2 class
solar flare, which started at 10:35 UT, reached the maximum at
10:38 UT, and ended at 10:44 UT (according to the GOES
classification). The flare was observed in the NOAA 8941 active
region (S18E09) of magnetic type .
The maximum of the
temperature of the plasma T=7 MK occurred at 10:36 UT,
while the maximum of the emission measure
cm-3 was at 10:44 UT (both values
are evaluated using GOES data). Between 10:36:51 UT and
10:38:04 UT TRACE (195 Å) recorded a spray ejected from
the central part of the active region. The average velocity of the
spray was 650 km s-1 (see Fig. 18). Radio
spikes were released at the same time as the spray was observed.
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Figure 14: Image of the NOAA 8999 active region taken with the TRACE (171 Å) telescope on 17 May 2000 at 15:46:07 UT. The arrows points to the regions with clearly visible motions of matter along the magnetic loops. |
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Figure 17: Dynamic radiospectrogram of the dm radio spikes recorded on 26 March 2000, beginning at 10:38:00 UT. Some spikes form clearly visible chains with drift in frequency. |
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The radio DCIM event started at 12:18:14 UT and ended at
12:22:36 UT. The dm radio spikes were recorded between 12:20:14 UT
and 12:20:40 UT, during the peak of the C7.4 solar flare (start
at 12:16 UT, maximum at 12:20 UT, end at 12:23 UT) in the
NOAA 9682 active region (N12E10) of magnetic type ,
noted
also as a 1N class H
flare between 12:18 UT and 12:32 UT
(see Figs. 19, 2). The
maximum of the temperature of the plasma T=12.3 MK
occurred at 12:20 UT, while the maximum of the emission measure
cm-3 was reached at 12:21 UT
(both values are evaluated using GOES data). The observed
radio spikes have internal structure and form chains. They
occurred during the bulk motion of the plasma along the long
loops, observed with the TRACE telescope in the 171 Å
band (see Fig. 20).
On 11 July 2000 we recorded four groups of radio spikes emitted during three separate radio events (see Figs. 21-24, respectively). The first event consisted of two separate groups of spikes, recorded by us during the DCIM-type radio event observed between 12:30:10 UT and 13:30:10 UT. The first group was recorded between about 13:16:03 UT and 13:16:44 UT, the second one between about 13:26:30 UT and 13:27:37 UT. The second group was observed also by Karlický and co-workers, who reported dm radio spikes between 13:25:40 UT and 13:27:40 UT in the frequency band 1.0-1.8 GHz (Karlický et al. 2001). The third group of spikes was recorded from 14:41:10 UT to 14:48:10 UT, during the next DCIM radio event observed by us between 14:34:50 UT and 14:51:30 UT. It started before the start of our observations. The last group of spikes, observed from 14:57:49 UT to 15:00:37 UT, occurred during the last radio event, observed from 14:57:40 UT to 15:02:20 UT.
All recorded spikes have no internal structure. The main
properties of the spikes are presented in Table 2. The emission of
the all groups of the spikes occurred during the X1.0 class solar
flare, which started at 12:12 UT and reached the maximum at
13:10 UT in the NOAA 9077 active region (N18E27) of magnetic type
(see Fig. 2).
The first two groups of spikes occurred after the maximum of this
flare, the other during its gradual phase. The images of the
active region taken with the SXT/Be119 telescope after 13:06 UT
show a Y-type interaction of the magnetic loops (see
Fig. 25). These loops probably form the main region
of energy release of the flare. The maximum of the temperature of
the plasma T=19.2 MK occurred at 12:16 UT, while the
maximum of the emission measure
cm-3 at 13:17 UT (both values are evaluated using GOES
data). Very likely the first, third and fourth groups of spikes
were emitted from this active region. An identification of the
source of the second group of spikes is problematic, while this
group of spikes (recorded between about 13:26:30 UT and
13:27:37 UT) is well correlated in time with an SF class H
flare, observed between 13:25 UT and 13:29 UT in the NOAA 9069
active region (S17W39) of magnetic type
.
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Figure 18: Image of the NOAA 8921 active region taken with TRACE (195 Å) on 26 March 2000 at 10:38:04 UT. |
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Figure 19: Dynamic radiospectrogram of the dm radio spikes recorded on 30 October 2001, beginning at 12:20:27 UT. |
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The radio event started at 12:47:25 UT, reached a maximum at
12:47:27 UT and ended at 12:47:45 UT. The radio spikes were
recorded between 12:47:25 UT and 12:47:39 UT (see
Fig. 26), during the gradual phase of the C2.3
class solar flare (start at 12:13 UT, maximum at 12:27 UT) in the
NOAA 9455 active region (S15W15) of magnetic type
(see Fig. 2). We have
recorded both types of spikes: with and without internal
structure. The maximum of the temperature of the plasma
T=10 MK occurred at 12:22 UT, while the maximum of the
emission measure
cm-3 at
12:29 UT (both values are evaluated using GOES data). UV
images of the active region taken with the TRACE telescope
in the 171 Å band show numerous interactions between two
systems of magnetic loops of different length as well as some
ejections of the plasma along the long loops heading outside the
region of interactions. The ejections were co-temporal with the
emission of the dm radio spikes (see Fig. 27).
In this paper we have described thirteen event, in which we
recognized eighteen groups of dm radio spike emission, composed of
various numbers of individual spikes of various characteristics.
The data were collected during 1990.4 h of observations in 357
observing days between February 2000 and December 2001. Using
X-ray data taken with Yohkoh, GOES and Interball
satellites, UV data taken with TRACE and SOHO
satellites and ground based observations made in the Hhydrogen line we have identified the most likely active solar
phenomena related to each radio event with spikes as well as
investigating the main morphological properties and evolution of
the spikes.
Eleven groups of spikes were emitted during the increasing phase of the solar flares, two groups were emitted during the peak of the flares and five groups were observed during the gradual phase of the flares (according to the GOES flux curves for the 1-8 Å band). Using the Yohkoh/HXT flux curves made in L and M1 channels, we found that six of eleven groups of spikes observed during the increasing phases undoubtedly occurred during the impulsive phase of the relevant flare. Five groups of dm radio spike emission were correlated in time with slow increases of the X-ray flux, leading to the solar flare. Using the GOES database, we found that no more than 2% of the solar flares were associated with radio spikes. However, probably all spikes are emitted as a result of some process connected with solar flares.
The analysis of the available observing materials shows that the emission of the dm radio spikes can be initiated in various configurations of the interacting magnetic fields and can be connected with various interactions between plasma and magnetic fields: interactions of the magnetic loops of Y and I configurations, bulk motions (ejections) of the plasma along long magnetic loops as well as rebuilding of the arcade of loops.
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Figure 20: Images of the NOAA 9682 active region taken with TRACE (171 Å) on 30 October 2001 at 12:16:22 UT ( left panel) and 12:17:45 UT ( right panel). The arrows show the direction of the plasma motion. |
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On the dynamic radiospectrograms of the investigated events we have found two kinds of well outlined structures formed by groups of individual spikes: chains of spikes and the different structures referred to as "columns''. The columns of spikes are formed by numerous individual spikes, emitted in a very short time range on various frequency in a whole observed band. In a frame of the column each individual spike can show its own positive (i.e. from low to high) or negative (i.e. from high to low) drift in frequency. The clear differences of the temporal evolution between chains and columns of spikes can be attributed to the differences in the structure of the radio sources.
We have evaluated the main observational parameters of the 5328 individual dm radio spikes. The shortest observed spike lasted 0.0026 s only, the longest one 0.284 s. The distribution of the spike durations is right-skewed with skewness equal to 1.64, its median is equal to 0.029 s, the mean is 0.036 s. 5165 spikes (97%) were shorter than 0.1 s, fulfilling the commonly accepted upper limit on spike duration. The presented durations of the spikes are much longer than mean duration of the spikes, equal to 10 ms, estimated for the same frequency band by Güdel & Benz (1990), and also are longer than the 10 ms mean duration of the spikes observed by Mészárosová et al. (2003). The differences cannot be attributed to the limited temporal resolution of the collected data.
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Figure 22: Dynamic radiospectrogram of the second group of dm radio spikes recorded on 11 July 2000, beginning at 13:27:25 UT. |
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Figure 25: Image of the NOAA 9077 active region taken with SXT/Be119 telescope on 11 July 2000 at 15:03:28 UT. |
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Figure 27: Images of the NOAA 9455 active region taken with TRACE (171 Å) on 14 May 2001 at 12:48:44 UT. |
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Thanks to the very high temporal resolution of the radiospectrograph used, we have found numerous individual dm radio emissions with visible subtle structure of the time-frequency distribution of the emission intensity; their dynamic spectrograms are strongly heterogeneous and fragmented. We have found that in a frame of the single radio event all emitted dm radio spikes are rather similar. Nevertheless, both types of spikes (with or without internal structure) can be emitted in the same event. Each spike has its own positive (i.e. from low to high) or negative (i.e. from high to low) drift in frequency of various speed (from tens of MHz per second up to greater than the highest measurable with our instrument, equal to 37.5 GHz per second). If these emissions are genuine, individual spikes with real internal subtle structure or if they are in fact very short lasting chains of tightly packed spikes with fast drifts in frequency should be addressed by future investigations.
The distribution of the durations of the 1699 spikes without internal structure shorter than 0.1 s is right-skewed with skewness equal to 1.86, its median is equal to 0.024 s and its mean is equal to 0.029 s. The distribution of durations of the 1837 spikes with internal structure shorter than 0.1 s is close to Gaussian (skewness equal to 0.12) with the median equal to 0.047 s and the mean equal to 0.046 s. The relative widths in frequency of these emissions are similar to the parameters of the "classical'' spikes without internal structure.
Taking into account all 13 events, seven events have a majority of spikes with negative drifts, five events have almost the same numbers of spikes with positive and negative drifts. 2769 spikes (52%) have negative drifts, 760 (14%) have positive drifts, the remaining spikes (1799) have immeasurable drifts. The drifts of the spikes with internal structure are distinctly slower than ones without structure.
The more extended results of the statistical investigation of the whole population of spikes as well as the properties of the individual spikes will be published in a separate paper (in preparation).
Acknowledgements
We are grateful to Dr G. D. Fleishman for many helpful remarks and comments during the writing of the paper. PR and MS were supported by the Polish State Committee for Scientific Research (KBN) grant number PBZ KBN 054/P03/2001, RF was supported by the KBN grant number 2 PO3D 001 23.
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Figure 3: Dynamic radiospectrogram of the dm radio spikes recorded on 15 March 2000, beginning at 12:20:40 UT. Some spikes form clearly visible chains. Here and in the next radiospectrograms the flux is scaled in relative units, the arrow point the spike presented in detail. |
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Figure 5: Dynamic radiospectrogram of the dm radio spikes recorded on 21 June 2000, beginning at 09:25:45 UT. One can notice both types of spikes: with and without internal structure; some of them are aggregated in columns of spikes. |
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Figure 9: Dynamic radiospectrogram of the dm radio spikes recorded on 23 April 2001, beginning at 10:14:58 UT. |
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Figure 15: Dynamic radiospectrogram of the dm radio spikes recorded on 21 May 2000, beginning at 09:39:28 UT. |
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Figure 16: Dynamic radiospectrogram of the dm radio spikes recorded on 26 March 2000, beginning at 10:38:00 UT. Some spikes show clearly visible internal subtle structure. |
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Figure 21: Dynamic radiospectrogram of the first group of dm radio spikes recorded on 11 July 2000, beginning at 13:16:20 UT. |
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Figure 23: Dynamic radiospectrogram of the third group of dm radio spikes recorded on 11 July 2000, beginning at 14:43:10 UT. |
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Figure 24: Dynamic radiospectrogram of the fourth group of dm radio spikes recorded on 11 July 2000, beginning at 14:59:05 UT. |
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Figure 26: Dynamic radiospectrogram of dm radio spikes recorded on 14 May 2001, beginning at 12:47:29 UT. |
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