White-light Emission and Non-thermal Electrons

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|second_author =  
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|publish_date = 8 October 2018
|publish_date = 8 October 2018
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(SOL2014-10-22T14:02).  
(SOL2014-10-22T14:02).  
Figure 1 shows the flare
Figure 1 shows the flare
-
observations from GOES, SDO/HMI continuum, SDO/AIA, IRIS, Hinode,
+
observations from  
 +
[https://www.swpc.noaa.gov/products/goes-x-ray-flux GOES],  
 +
[http://hmi.stanford.edu SDO/HMI] continuum,  
 +
[https://en.wikipedia.org/wiki/Solar_Dynamics_ObservatorySDO/AIA],  
 +
[http://iris.lmsal.com IRIS],  
 +
[http://global.jaxa.jp/projects/sat/solar_b/ Hinode],
and RHESSI spacecraft.  
and RHESSI spacecraft.  
These multi-wavelength spectroscopic observations show
These multi-wavelength spectroscopic observations show
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(bottom) for the bright kernel from the EIS spectral lines: He II,
(bottom) for the bright kernel from the EIS spectral lines: He II,
Fe XII, Fe XV, and Fe XXIII. The vertical dashed lines correspond
Fe XII, Fe XV, and Fe XXIII. The vertical dashed lines correspond
-
to the observing times of the panel (b).  (b) Doppler velocities
+
to the observing times of the panel (b).   
 +
<br>
 +
(b) Doppler velocities
from EIS and IRIS as a function of the peak formation temperature
from EIS and IRIS as a function of the peak formation temperature
for the bright kernel at different times, the impulsive phase (top)
for the bright kernel at different times, the impulsive phase (top)
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]]
]]
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== White light flare produced by non-thermal electrons ==
+
== White light emission produced by non-thermal electrons ==
The continuum enhancement of the flare kernel (WLF) implies that
The continuum enhancement of the flare kernel (WLF) implies that
the flare energy is transported to the lower atmosphere and produces
the flare energy is transported to the lower atmosphere and produces
-
the chromospheric and photospheric emission. To understand the
+
the chromospheric and photospheric emission.  
-
heating process and how the WLF kernel is produced, We tried to
+
To understand the heating process and how the WLF kernel is produced,  
-
estimate the deposited and dissipated energies from the X-ray, UV,
+
we tried to estimate the deposited and dissipated energies from the X-ray, UV,
-
and continuum intensity and compare them. Figure 3 shows the IRIS
+
and continuum intensities.  
-
Mg II spectra in the flare kernel and the temporal variation of the
+
Figure 3 shows the IRIS  
 +
[https://ned.ipac.caltech.edu/level5/Ewald/Grotrian/frames.html Mg II]
 +
spectra in the flare kernel and the temporal variation of the
estimated energy flux from the X-ray, UV, and continuum intensity.
estimated energy flux from the X-ray, UV, and continuum intensity.
The Mg II subordinate line (Mg II triplet) is in emission during
The Mg II subordinate line (Mg II triplet) is in emission during
the impulsive phase of the flare while the Mg II triplet mostly was
the impulsive phase of the flare while the Mg II triplet mostly was
-
observed as absorption in quiet regions (Figure 3a). It has been
+
observed as absorption in quiet regions (Figure 3a).  
-
reported that the strong enhancement of the intensity ratio of the
+
It has been reported that a strong enhancement of the intensity  
-
Mg II core to wing (emission) implies the existence of a steep
+
ratio of the Mg II core to wing (emission) implies the existence of a steep
-
temperature gradient and heating [refs. 2,4]. Taking the measured
+
temperature gradient and heating [Refs. 2, 4].  
-
energy flux from this spectra as an estimate of the amount of energy
+
Taking the measured energy flux from this spectra as an estimate of the  
-
dissipated in the chromosphere, it is about 6%22% of the energy
+
amount of energy dissipated in the chromosphere, it is about 6-22% of  
-
deposited by the accelerated non-thermal electrons as measured by
+
the energy deposited by the accelerated non-thermal electrons as measured by
-
RHESSI, assuming the cutoff energy of 3040 keV (Figure 3b). This
+
RHESSI, assuming the cutoff energy of 30-40 keV (Figure 3b).  
-
result implies that the majority of the energy from the non-thermal
+
This result implies that the majority of the energy from the non-thermal
electrons accelerated in the corona is still available to directly
electrons accelerated in the corona is still available to directly
-
produce a WLF in this event. The correlated temporal variations of
+
produce a WLF in this event.  
-
the HXR, WL, explosive evaporation flows, and the Mg II line response,
+
The correlated temporal variations of the HXR, WL, explosive evaporation  
 +
flows, and the Mg II line response,
together with the comparison of the energy flux through the corona
together with the comparison of the energy flux through the corona
to the chromosphere, imply that the flare heating and evaporation
to the chromosphere, imply that the flare heating and evaporation
flow are driven by non-thermal electrons, though we cannot rule out
flow are driven by non-thermal electrons, though we cannot rule out
-
a possible contribution from Alfvn wave heating.
+
a possible contribution from  
-
 
+
[https://en.wikipedia.org/wiki/Alfvén_wave Alfv&eacute;n wave] heating.
-
== Conclusions ==
+
-
 
+
-
We investigated the temporal variation of the spectral properties
+
-
of a WLF kernel and estimated the energy flux at different wavelengths.
+
-
By the comparison of the measured spectral properties and energy
+
-
fluxes in different wavelengths, it shows that the flare could be
+
-
directly produced by non-thermal electrons. The flare we investigated
+
-
is quite strong X1.6 classso while the accelerated non-thermal
+
-
electrons from this strong flare could produce a WLF directly in
+
-
this event, we still do not know whether most WLFs can be produced
+
-
by the energy from the accelerated electrons or whether this process
+
-
works even in small flares. Therefore, further studies applying
+
-
similar techniques to other flares that produce WL emission are
+
-
required to confirm whether they can also be produced directly or
+
-
not.
+
-
 
+
-
 
+
-
Figure 3.  
+
 +
[[File:334f3.png|600px|thumb|center| Figure 3: 
(a) IRIS detector images of the Mg II h & k spectral windows overlaid
(a) IRIS detector images of the Mg II h & k spectral windows overlaid
with the averaged spectral line profiles at the location marked by
with the averaged spectral line profiles at the location marked by
Line 160: Line 153:
12:00 UT). The arrows indicate the emission of the Mg II triplet
12:00 UT). The arrows indicate the emission of the Mg II triplet
lines.   
lines.   
 +
<br>
(b) The energy flux of the bright kernel during the flare
(b) The energy flux of the bright kernel during the flare
impulsive phase estimated from the RHESSI HXR emission with different
impulsive phase estimated from the RHESSI HXR emission with different
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and 50 keV (dotted line), the Mg II triplet intensity observed by
and 50 keV (dotted line), the Mg II triplet intensity observed by
IRIS, and the WL continuum emission from SDO/HMI.
IRIS, and the WL continuum emission from SDO/HMI.
 +
]]
 +
== Conclusions ==
 +
 +
We have investigated the temporal variation of the spectral properties
 +
of a WLF kernel and estimated the energy flux at different wavelengths.
 +
By comparison of the measured spectral properties and energy
 +
fluxes in different wavelengths, it appears that the flare emissions
 +
could have been directly produced by non-thermal electrons.
 +
The flare we investigated is quite strong (X1.6 classs), and while
 +
the accelerated non-thermal electrons from this strong flare could
 +
produce a WLF directly in this event, we still do not know whether
 +
most WLFs can be produced by the energy from the accelerated electrons.
 +
We particularly do not know yet whether this process
 +
works even in small flares.
 +
Therefore, further studies applying
 +
similar techniques to other flares that produce visible continuum emission are
 +
required to confirm whether they can also be produced directly or
 +
not.
== References ==
== References ==

Latest revision as of 20:14, 7 December 2018


Nugget
Number: 334
1st Author: Kyoung-Sun LEE
2nd Author:
Published: 8 October 2018
Next Nugget: CORONAS/SPIRIT Mg XII and Nanoflares
Previous Nugget: Coronal Hard X-ray Sources Revisited
List all



Contents

Introduction

A solar flare produces emissions detected all across the electromagnetic spectrum, and thus involving all "layers" of the solar atmosphere. In particular the chromosphere may contain some of the decisive physics, based upon the newest data.

Recent space-borne UV - EUV - X-ray spectroscopic observations allow us to investigate the flare plasma properties and their temporal evolution throughout the solar atmosphere, chromosphere to the corona. For example, the Doppler velocity from the UV-EUV spectra gives information about plasma flows in the solar atmosphere which can be compared with the velocities from simulation models, helping to understand the flare heating process [Ref. 1]. Our diagnostic abilities for temperature and density have been greatly extended recently with wide wavelength coverage of the space-borne spectroscopy and simulations [Ref. 2]. Taking advantage of the combining UV-EUV imaging spectroscopy, in this Nugget, we report the flare plasma dynamics and energy flux through the solar atmosphere during a white-light flare (WLF) using the multiple spectroscopic observations, and then, we try to understand how the visible continuum is produced [Ref. 3].

A flare kernel observed by SDO, IRIS, Hinode, and RHESSI

NOAA AR 12192 was the largest active region in Solar Cycle 24. Many coordinated observations concentrated on this region, and an X-class flare was observed by multiple space-based observations covering the whole flare duration (SOL2014-10-22T14:02). Figure 1 shows the flare observations from GOES, SDO/HMI continuum, [1], IRIS, Hinode, and RHESSI spacecraft. These multi-wavelength spectroscopic observations show that the flare kernel was localized during the impulsive phase and that the HXR emission, chromospheric intensity, and WL continuum emission in the kernel are spatially and temporally correlated. Figure 2 shows the Doppler velocity and line width of UV-EUV spectra in the localized bright kernel with a time and a peak formation temperature. As Figure 2 shows, we found that strong evaporation flows (up-flows in hot lines) occurs and there are strong enhancements in line width during the first peak of the HXR emission, which is also coincident with the timing of the WLF. This may indicate that electron beam heating produces strong evaporation flows and there is turbulence from the reconnection or non-thermal electron heating.

Figure 1: Context images of the X1.6 flare on 2014 October 22 14:06 UT. The arrows indicate the bright kernel we studied.
(a) The GOES X-ray light curve (top), its time derivative (middle), and the RHESSI count rates for the different energy bands (bottom). The vertical dashed lines mark the times of the three peaks in the time derivative of the GOES X-ray light curve.
(b) SDO/AIA 1600Â image at the timing of the first hard X-ray peak (~14:06 UT).
(c) SDO/HMI continuum and a running difference image at 14:05:45 UT.
(d) IRIS C II 1330 slit jaw images overlaid with EIS 195 intensity contours (gray line) and the location of IRIS raster (white box) at 14:06 UT.
(e) HMI continuum difference image with HXR (30100 keV) and SXR (1225 keV) contours overlaid from the RHESSI image covering 14:05:3214:06:32 UT. Red and green contours correspond to 50%, 60%, 70%, 80%, and 90% of the HXR and SXR intensity, respectively.
Figure 2: (a) Temporal variation of the Doppler velocity (top) and line width (bottom) for the bright kernel from the EIS spectral lines: He II, Fe XII, Fe XV, and Fe XXIII. The vertical dashed lines correspond to the observing times of the panel (b).
(b) Doppler velocities from EIS and IRIS as a function of the peak formation temperature for the bright kernel at different times, the impulsive phase (top) and the gradual phase (bottom). Diamonds indicate the Doppler velocities from the IRIS spectra while crosses represent the Doppler velocities from the EIS spectra. Black and red indicate the velocities calculated from the single and multiple Gaussian components relative to the rest wavelengths.

White light emission produced by non-thermal electrons

The continuum enhancement of the flare kernel (WLF) implies that the flare energy is transported to the lower atmosphere and produces the chromospheric and photospheric emission. To understand the heating process and how the WLF kernel is produced, we tried to estimate the deposited and dissipated energies from the X-ray, UV, and continuum intensities. Figure 3 shows the IRIS Mg II spectra in the flare kernel and the temporal variation of the estimated energy flux from the X-ray, UV, and continuum intensity. The Mg II subordinate line (Mg II triplet) is in emission during the impulsive phase of the flare while the Mg II triplet mostly was observed as absorption in quiet regions (Figure 3a). It has been reported that a strong enhancement of the intensity ratio of the Mg II core to wing (emission) implies the existence of a steep temperature gradient and heating [Refs. 2, 4]. Taking the measured energy flux from this spectra as an estimate of the amount of energy dissipated in the chromosphere, it is about 6-22% of the energy deposited by the accelerated non-thermal electrons as measured by RHESSI, assuming the cutoff energy of 30-40 keV (Figure 3b). This result implies that the majority of the energy from the non-thermal electrons accelerated in the corona is still available to directly produce a WLF in this event. The correlated temporal variations of the HXR, WL, explosive evaporation flows, and the Mg II line response, together with the comparison of the energy flux through the corona to the chromosphere, imply that the flare heating and evaporation flow are driven by non-thermal electrons, though we cannot rule out a possible contribution from Alfvén wave heating.

Figure 3: (a) IRIS detector images of the Mg II h & k spectral windows overlaid with the averaged spectral line profiles at the location marked by the two horizontal green lines. The solid lines represent the line profiles during the pre-flare (top) and impulsive phase (bottom) and dotted lines correspond the line profile before the flare (around 12:00 UT). The arrows indicate the emission of the Mg II triplet lines.
(b) The energy flux of the bright kernel during the flare impulsive phase estimated from the RHESSI HXR emission with different threshold energies of 30 keV (solid line), 40 keV (dashed line), and 50 keV (dotted line), the Mg II triplet intensity observed by IRIS, and the WL continuum emission from SDO/HMI.

Conclusions

We have investigated the temporal variation of the spectral properties of a WLF kernel and estimated the energy flux at different wavelengths. By comparison of the measured spectral properties and energy fluxes in different wavelengths, it appears that the flare emissions could have been directly produced by non-thermal electrons. The flare we investigated is quite strong (X1.6 classs), and while the accelerated non-thermal electrons from this strong flare could produce a WLF directly in this event, we still do not know whether most WLFs can be produced by the energy from the accelerated electrons. We particularly do not know yet whether this process works even in small flares. Therefore, further studies applying similar techniques to other flares that produce visible continuum emission are required to confirm whether they can also be produced directly or not.

References

[1] "Simultaneous IRIS and Hinode/EIS Observations and Modeling of the 2014 October 27 X2.0 Flare"

[2] "The Formation of IRIS Diagnostics. IV. The Mg II Triplet Lines as a New Diagnostic for Lower Chromospheric Heating"

[3] "Hot explosions in the cool atmosphere of the Sun"

[4]"IRIS, Hinode, SDO, and RHESSI Observations of a White Light Flare Produced Directly by Nonthermal Electrons"

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