Presentation is loading. Please wait.

Presentation is loading. Please wait.

RHESSI and Radio Imaging Observations of Microflares M.R. Kundu, Dept. of Astronomy, University of Maryland, College Park, MD G. Trottet, Observatoire.

Published byMoses Wright Modified over 8 years ago

Similar presentations

Presentation on theme: "RHESSI and Radio Imaging Observations of Microflares M.R. Kundu, Dept. of Astronomy, University of Maryland, College Park, MD G. Trottet, Observatoire."— Presentation transcript:

1 RHESSI and Radio Imaging Observations of Microflares M.R. Kundu, Dept. of Astronomy, University of Maryland, College Park, MD G. Trottet, Observatoire de Paris/Meudon, France V.I. Garaimov, Dept. of Astronomy, University of Maryland, College Park, MD P.C. Grigis, Institute of Astronomy, ETH Zurich, CH-8092 Zurich, Switzerland E.J.Schmahl, Dept. of Astronomy, University of Maryland, College Park, MD and Lab for Astronomy and Solar Physics, NASA/GSFC

2 ABSTRACT We present the analysis of five microflares Three observed simultaneously by RHESSI in hard X-rays and Nobeyama RadioHeliograph (NoRH) in microwaves (17 GHz) and Two observed by RHESSI and Nancay RadioHeliograph (NRH) at metric wavelengths (150-450 MHz). Since we have no radio imaging telescopes simultaneously operating at microwave and meter wavelengths in the same time zone, we use a different set of microevents for comparison with metric wavelength counterparts in contrast to that used for comparison with microwave events. This is because we are interested in using the locations and other imaging characteristics of the events from both RHESSI and Nancay instead of just temporal correlation. Here we describe the properties of five events -- three in microwaves and two at metric wavelengths.

3 Three microwave events corresponding to RHESSI microflares occurred in active region 9934 : 2002 May 3 03:58 ; 2002 May 4 05:08 ; 2002 May 2 01:52 UT AR 9934 was a complex region which contained a sunspot with a strong negative polarity of the magnetic field on the north side and a bipolar region on the south side. MDI images show fast evolution of the south part of the region. TRACE images show many small loops in the south and the complex loop connecting the north sunspot to the south side of the region. NoRH 17-GHz maps show loop-like structure with a maximum above the sunspot and it connects to the south side of the AR. RHESSI maps superimposed on the NoRH maps show that X-ray emission in the range 3-25 keV are located inside the radio contours. THE 2002 MAY EVENTS OBSERVED AT NOBEYAMA

4 During all three events HXR emission was located in the south part of the AR. RHESSI maps for 2002 May 3 (event 1) clearly show an X-ray loop at 3-6 keV and two footpoints of the loop in the 6-12 and 12-25 keV ranges. These footpoints are located above opposite magnetic polarities as seen in overlays of hard X-ray images on the MDI image. For 2002 May 4 (event 2) HXR images show a small X-ray loop, located close to the same position as previous event. Footpoints of the X-ray loop are not resolved. Overlays of HXR images on the MDI image shows that the X-ray loop was located above the magnetic neutral line and it connected two regions with opposite magnetic polarities. During both events HXR emission was observed below 25 keV. Total radio flux from the X-ray emitting active region was less than 0.5 sfu. No significant polarization of the radio emission was observed in either case.

5 2002 May 2 (event 3) is one of several microflares observed on this day, which originated in the NE part of the active region. At 01:52:10 UT RHESSI images in 3 energy bands 3-6 keV, 6-12 keV and 12-25 keV overlie a 17-GHz NE source which occupies mostly an MDI negative polarity, implying that the HXR source may be situated above the strongest microwave source -- probably one footpoint of the microwave flaring loop. The NE source and another SW source seem to contribute to the microflare emission at the same time as judged from the time profiles. For the maximum phase of 2002 May 3 (event 1) the HXR spectrum was calculated. It could be fitted by three components: thermal bremsstrahlung, atomic emission lines, and power law spectrum. Temperature of the thermal component was about 1.6 keV; the emission measure was about 6 10 46 cm-3. Slope of the power law is -3.2.

6 TRACE images of the AR 9934 with MDI contours 2002 May 03 2002 May 04

7 Evolution of the magnetic field The southern part of the active region shows fast evolution of the magnetic field.

8 May 02, 2002 The microflare concerned occurs at 01:52 UT (first row). The RHESSI and NoRH images show co-located sources superposed on a MDI magnetogram.

9 MDI images with 17GHz and RHESSI contours of AR 9934 2002 May 03 May 04, 2002

10 Time profiles of 17GHz and X-Ray time profile and spectrogram 2002 May 03 The dashed vertical line indicates the start of the microevent.

11 May 03, 2002 Left: time profiles at 17 GHz and for GOES and RHESSI (3-25 keV) Right: contour maps at 17 GHz and HXR superimposed on MDI magnetogram The The The microflare concerned (03:58) is shown in the bottom row. HXR loop at 3-6 keV; two footpoints in 6-25 keV.

12 May 04, 2002 Left: time profiles at 17 GHz and for GOES and RHESSI (3-25 keV) Right: contour maps at 17 GHz and HXR superimposed on MDI magnetogram The event concerned starts at 0:508 UT (first row). Note a small X- ray loop close to the May 3 location. The HXR source is compact with unresolved footpoints.

13 X-ray spectrum fitted by three components: thermal bremsstrahlung, atomic lines, and power law Temperature of the thermal component is about 1.6 keV; emission measure is about 6 10 46 cm -3. Slope of the power law is -3.2.

14 RHESSI HXR spectra for event 1 (May 3). Each panel shows a 5-component fit for a 12-s time bin using thermal, atomic line emission and nonthermal bremsstrahlung. 12.812.611.312.3E turn (keV) 0.1530.2190.3490.134F20 6.034.483.333.62  13.79.689.557.25EM (10 46 cm -3 ) 17.317.816.516.3T1 (MK) 4321Time bin The components are: Temperature (T), emission measure (E), spectral index (  ), 20-keV flux (F20), and lower cutoff (E turn )

15 Conclusions We have detected microwave (17 GHz) counterparts of RHESSI microflares observed in the energy range 3-50 keV. The microwave emission comes from the foot points (for higher energies), and from the entire small (mini) flaring loop (for lower energies). The relative positions of microwaves and hard X-rays in the higher energy channels are as they should be in normal flares. Sometimes the two (microwave & hard X-ray) sources coincide, at other times the two are at opposite ends of the mini flaring loop. One sees the mini flaring loops clearly in NoRH images. The hard X-ray spectrum of microwave associated RHESSI micro flares can be fit by a thermal component (EM~6*10 46 cm -3 at 3-6 keV) at low energies and (sometimes) a nonthermal component (with slope -3.2) at higher energies. At metric wavelengths the type III bursts are often spatially associated with RHESSI microflares. This must have important implications in the propagation of energetic electrons up thru the corona. This result combined with microwave results should provide a good understanding of the topology of coronal structures in which energetic HXR emitting electrons propagate.

16 Nancay events Unfortunately we have no radio imaging telescopes simultaneously operating at Microwave and meter wavelengths in the same time zone. So we’ve used the Nancay(France) metric radioheliograph at 150- 450 MHz to study metric counterparts of RHESSI micro-flares and used a different set of microflares for comparison with metric events as opposed to that used for comparison with microwave events. This is because we want to use the locations of events from both RHESSI and Nancay and not just temporal correlation. Here we present a preliminary analysis of such a study. Since both RHESSI HXR and metric type IIIs are produced by beams of electrons, type IIIs are the obvious candidates for such a comparison. We confirmed our identification of bursts by using Potsdam spectral data.

17 Aug. 05, 2003 Top Left: RHESSI time profile of a microflare, along with Nancay burst time profiles at 150,164,236 MHz. Bottom Left: EIT image with RHESSI and Type III positional data at three frequencies. The RHESSI source is very compact. Middle top panel: MDI image with RHESSI microflare position. Right top: Potsdam type III bursts

18 Sep. 03, 2003 Top Left: RHESSI time profile of a micro flare, along with Nancay burst time profiles at 150,164,236,327,410 MHz. Bottom Left: EIT image with RHESSI and Type III positional data at five frequencies. Note the very compact RHESSI source. Right top: Potsdam type III bursts

19 Concluding Remarks Our main conclusion is that RHESSI micro flares are often spatially associated with metric type III bursts. This must have important implications in the propagation of energetic electrons up thru the corona. This result combined with microwave results should provide a good understanding of the topology of coronal structures in which energetic HXR emitting electrons propagate.

Download ppt "RHESSI and Radio Imaging Observations of Microflares M.R. Kundu, Dept. of Astronomy, University of Maryland, College Park, MD G. Trottet, Observatoire."

Similar presentations

NBYM 2006 A major proton event of 2005 January 20: propagating supershock or superflare? V. Grechnev 1, V. Kurt 2, A. Uralov 1, H.Nakajima 3, A. Altyntsev.

NBYM 2006 A major proton event of 2005 January 20: propagating supershock or superflare? V. Grechnev 1, V. Kurt 2, A. Uralov 1, H.Nakajima 3, A. Altyntsev.
Masuda Flare: Remaining Problems on the Looptop Impulsive Hard X-ray Source in Solar Flares Satoshi Masuda (STEL, Nagoya Univ.)

Masuda Flare: Remaining Problems on the Looptop Impulsive Hard X-ray Source in Solar Flares Satoshi Masuda (STEL, Nagoya Univ.)
THE IMPULSIVE X-RAY RESPONSE IN FLARE FOOTPOINTS TOMASZ MROZEK WROCLAW UNIWERSITY ASTRONOMICAL INSTITUTE POLAND.

THE IMPULSIVE X-RAY RESPONSE IN FLARE FOOTPOINTS TOMASZ MROZEK WROCLAW UNIWERSITY ASTRONOMICAL INSTITUTE POLAND.
RHESSI observations of LDE flares – extremely long persisting HXR sources Mrozek, T., Kołomański, S., Bąk-Stęślicka, U. Astronomical Institute University.

RHESSI observations of LDE flares – extremely long persisting HXR sources Mrozek, T., Kołomański, S., Bąk-Stęślicka, U. Astronomical Institute University.
Flare energy release and wave dynamics in nearby sunspot Solar and Stellar Flares, Observations, simulations and synergies June 23 - 27, 2013, Prague,

Flare energy release and wave dynamics in nearby sunspot Solar and Stellar Flares, Observations, simulations and synergies June , 2013, Prague,
Spatial and temporal relationships between UV continuum and hard x-ray emissions in solar flares Aaron J. Coyner and David Alexander Rice University June.

Spatial and temporal relationships between UV continuum and hard x-ray emissions in solar flares Aaron J. Coyner and David Alexander Rice University June.
Microwave and hard X-ray imaging observations of energetic electrons in solar flares: event of 2003 June 17 Kundu, M R., Schmahl, E J, and White, S M.

Microwave and hard X-ray imaging observations of energetic electrons in solar flares: event of 2003 June 17 Kundu, M R., Schmahl, E J, and White, S M.
Multi-Wavelength Studies of Flare Activities with Solar-B ASAI Ayumi Kwasan Observatory, Kyoto University Solar-B Science February 4, 2003.

Multi-Wavelength Studies of Flare Activities with Solar-B ASAI Ayumi Kwasan Observatory, Kyoto University Solar-B Science February 4, 2003.
Relations between concurrent hard X-ray sources in solar flares M. Battaglia and A. O. Benz Presented by Jeongwoo Lee NJIT/CSTR Journal Club 2007 October.

Relations between concurrent hard X-ray sources in solar flares M. Battaglia and A. O. Benz Presented by Jeongwoo Lee NJIT/CSTR Journal Club 2007 October.
X-Ray Observation and Analysis of a M1.7 Class Flare Courtney Peck Advisors: Jiong Qiu and Wenjuan Liu.

X-Ray Observation and Analysis of a M1.7 Class Flare Courtney Peck Advisors: Jiong Qiu and Wenjuan Liu.
Working Group 2 - Ion acceleration and interactions.

Working Group 2 - Ion acceleration and interactions.
RHESSI/GOES Observations of the Non-flaring Sun from 2002 to 2006. J. McTiernan SSL/UCB.

RHESSI/GOES Observations of the Non-flaring Sun from 2002 to J. McTiernan SSL/UCB.
Hard X-ray footpoint statistics: spectral indices, fluxes, and positions Pascal Saint-Hilaire 1, Marina Battaglia 2, Jana Kasparova 3, Astrid Veronig 4,

Hard X-ray footpoint statistics: spectral indices, fluxes, and positions Pascal Saint-Hilaire 1, Marina Battaglia 2, Jana Kasparova 3, Astrid Veronig 4,
White-Light Flares: TRACE and RHESSI Observations H. Hudson (UCB), J. Wolfson (LMSAL) & T. Metcalf (CORA)

White-Light Flares: TRACE and RHESSI Observations H. Hudson (UCB), J. Wolfson (LMSAL) & T. Metcalf (CORA)
RHESSI/GOES Xray Analysis using Multitemeprature plus Power law Spectra. J.McTiernan (SSL/UCB)

RHESSI/GOES Xray Analysis using Multitemeprature plus Power law Spectra. J.McTiernan (SSL/UCB)
FLARE ENERGETICS:TRACE WHITE LIGHT AND RHESSI HARD X-RAYS* L. Fletcher (U. Glasgow), J. C. Allred (GSFC), I. G. Hannah (UCB), H. S. Hudson (UCB), T. R.

FLARE ENERGETICS:TRACE WHITE LIGHT AND RHESSI HARD X-RAYS* L. Fletcher (U. Glasgow), J. C. Allred (GSFC), I. G. Hannah (UCB), H. S. Hudson (UCB), T. R.
RHESSI/GOES Xray Analysis using Multitemeprature plus Power law Spectra. J.McTiernan (SSL/UCB) ABSTRACT: We present spectral fits for RHESSI and GOES solar.

RHESSI/GOES Xray Analysis using Multitemeprature plus Power law Spectra. J.McTiernan (SSL/UCB) ABSTRACT: We present spectral fits for RHESSI and GOES solar.
3 November 2003 event HXR/Gamma-ray and radio observations Rhessi_workshop.

3 November 2003 event HXR/Gamma-ray and radio observations Rhessi_workshop.
Search for X-ray emission from coronal electron beams associated with type III radio bursts Pascal Saint-Hilaire, Säm Krucker, Robert P. Lin Space Sciences.

Search for X-ray emission from coronal electron beams associated with type III radio bursts Pascal Saint-Hilaire, Säm Krucker, Robert P. Lin Space Sciences.
White-Light Flares and HESSI Prospects H. S. Hudson (UCB and SPRC) March 8, 2002.

White-Light Flares and HESSI Prospects H. S. Hudson (UCB and SPRC) March 8, 2002.

Similar presentations

Ads by Google