Multi-wavelength fine structure and mass flows in solar microflares
Berkebile-Stoiser S.1, Gömöry P.1,2,
Veronig A. M.1, Rybak J.2, Sutterlin P.3
1 IGAM/Kanzelhoehe Observatory, Institute of Physics, Universiteat Graz,
Universiteatsplatz 5, A-8010 Graz, Austria
2 Astronomical Institute of the Slovak Academy of Sciences,
SK-05960 Tatranská Lomnica, Slovakia
3 Institute for Solar Physics, The Royal Swedish Academy of Sciences,
Alba Nova University Center, 106 91 Stockholm, Sweden
Abstract:
Aims. We study the multi-wavelength characteristics at high spatial resolution, as well as
chromospheric evaporation signatures of solar microflares. To this end, we analyze the fine structure
and mass flow dynamics in the chromosphere, transition region and corona of three homologous microflares
(GOES class A9/0.7 with/without background), which occurred on July 4, 2006 in AR 10898.
Methods. A multi-wavelength analysis using temporally and spatially highly resolved imaging
data from the Dutch open telescope (H-alpha, Ca II H), the transition region and coronal explorer (17.1 nm),
the extreme-ultraviolet imaging telescope (19.5 nm), and the Reuven Ramaty high energy solar spectroscopic
imager was carried out. EUV line spectra provided by the coronal diagnostic spectrometer are searched for
Doppler shifts in order to study associated plasma flows at chromospheric (He I, T ~ 3.9x10^4 K), transition
region (e.g. O V, T ~ 2.6x10^5 K), and coronal temperatures (Si XII, T ~ 2x10^6 K). RHESSI X-ray spectra
provide information about non-thermal electrons.
Results. The multi-wavelength appearance of the microflares is in basic agreement with the
characteristics of large flares. For the first event, a complex flare sequence is observed in TRACE
17.1 nm images (T ~ 1 MK), which show several brightenings, narrow loops of enhanced emission, and an
EUV jet. EIT 19.5 nm data (T ~ 1.5 MK) exhibit similar features for the third event. DOT measurements
show finely structured chromospheric flare brightenings for all three events, loop-shaped fibrils of
increased emission between H-alpha brightenings, as well as a similar feature in Ca II. For all three
events, a RHESSI X-ray source (3-8 keV, T > 10 MK) is located in between two chromospheric brightenings
situated in magnetic flux of opposite polarity. We find the flow dynamics associated with the events to
be very complex. In the chromosphere and transition region, CDS observed downflows for the first (v < 40 km/s),
and upflows for the second event (v < 40 km/s). During the third microflare, we find upflows of < 20 km/s
and also weak downflows of <20 km/s in two separate brightenings. For all three microflares, multi-component
fitting is needed for several profiles of He I, O V, and Ne VI lines observed at the flare peaks, which
indicate spatially unresolved, oppositely directed flows of <180 km/s. We interpret these flows as twisting
motions of the flare loops. Loop-shaped fibrils in between H-alpha brightenings showing opposite flow directions
(v ~ 5 km/s) are also observed in DOT H-alpha Dopplergrams. RHESSI X-ray spectra show evidence of non-thermal
bremsstrahlung for two of the three microflares. The electron beam flux density deposited in the chromosphere
for these events is estimated to straddle the threshold heating flux between gentle and explosive evaporation.