3,128 research outputs found
Explosive events on sub-arcsecond scale in IRIS observations: a case study
We present study of a typical explosive event (EE) at sub-arcsecond scale
witnessed by strong non-Gaussian profiles with blue- and red-shifted emission
of up to 150 km/s seen in the transition-region Si IV 1402.8 \AA, and the
chromospheric Mg II k 2796.4 \AA\ and C II 1334.5 \AA\ observed by the
Interface Region Imaging Spectrograph at unprecedented spatial and spectral
resolution. For the first time a EE is found to be associated with very
small-scale (120 km wide) plasma ejection followed by retraction in the
chromosphere. These small-scale jets originate from a compact bright-point-like
structure of 1.5" size as seen in the IRIS 1330 \AA\ images. SDO/AIA and
SDO/HMI co-observations show that the EE lies in the footpoint of a complex
loop-like brightening system. The EE is detected in the higher temperature
channels of AIA 171 \AA, 193 \AA\ and 131 \AA\ suggesting that it reaches a
higher temperature of log T (K). Brightenings observed in the AIA
channels with durations 90--120 seconds are probably caused by the plasma
ejections seen in the chromosphere. The wings of the C II line behave in a
similar manner as the Si IV's indicating close formation temperatures, while
the Mg II k wings show additional Doppler-shifted emission. Magnetic
convergence or emergence followed by cancellation at a rate of
Mx s is associated with the EE region. The combined changes of the
locations and the flux of different magnetic patches suggest that magnetic
reconnection must have taken place. Our results challenge several theories put
forward in the past to explain non-Gaussian line profiles, i.e. EEs. Our case
study on its own, however, cannot reject these theories, thus further in-depth
studies on the phenomena producing EEs are required.Comment: 16 figures, accepted for publication in Ap
Narrow-line-width UV bursts in the transition region above Sunspots observed by IRIS
Various small-scale structures abound in the solar atmosphere above active
regions, playing an important role in the dynamics and evolution therein. We
report on a new class of small-scale transition region structures in active
regions, characterized by strong emissions but extremely narrow Si IV line
profiles as found in observations taken with the Interface Region Imaging
Spectrograph (IRIS). Tentatively named as Narrow-line-width UV bursts (NUBs),
these structures are located above sunspots and comprise of one or multiple
compact bright cores at sub-arcsecond scales. We found six NUBs in two datasets
(a raster and a sit-and-stare dataset). Among these, four events are
short-living with a duration of 10 mins while two last for more than 36
mins. All NUBs have Doppler shifts of 15--18 km/s, while the NUB found in
sit-and-stare data possesses an additional component at 50 km/s found
only in the C II and Mg II lines. Given that these events are found to play a
role in the local dynamics, it is important to further investigate the physical
mechanisms that generate these phenomena and their role in the mass transport
in sunspots.Comment: 8 pages, 4 figures and 1 table, accepted for publication in ApJ
Plasma parameters and geometry of cool and warm active region loops
How the solar corona is heated to high temperatures remains an unsolved
mystery in solar physics. In the present study we analyse observations of 50
whole active-region loops taken with the Extreme-ultraviolet Imaging
Spectrometer (EIS) on board the Hinode satellite. Eleven loops were classified
as cool (<1 MK) and 39 as warm (1-2 MK) loops. We study their plasma parameters
such as densities, temperatures, filling factors, non-thermal velocities and
Doppler velocities. We combine spectroscopic analysis with linear force-free
magnetic-field extrapolation to derive the three-dimensional structure and
positioning of the loops, their lengths and heights as well as the magnetic
field strength along the loops. We use density-sensitive line pairs from Fe
XII, Fe XIII, Si X and Mg VII ions to obtain electron densities by taking
special care of intensity background-subtraction. The emission-measure loci
method is used to obtain the loop temperatures. We find that the loops are
nearly isothermal along the line-of-sight. Their filling factors are between 8%
and 89%. We also compare the observed parameters with the theoretical RTV
scaling law. We find that most of the loops are in an overpressure state
relative to the RTV predictions. In a followup study, we will report a heating
model of a parallel-cascade-based mechanism and will compare the model
parameters with the loop plasma and structural parameters derived here.Comment: ApJ, accepted for publicatio
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