On the outflow at coronal heights or the way I learned to listen to Philippe
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1 Outline On the outflow at coronal heights or the way I learned to listen to Philippe Tayeb Aiouaz 1,2 Hardi Peter 1 Philippe Lemaire 2 1 Kiepenheuer Institut für Sonnenphysik(KIS), Freiburg, Germany 2 Institut d Astrophysique Spatiale(IAS), Orsay, France November 24
2 Outline Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
3 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
4 Previous works Gebbie et al. (1981): Si IV and C IV with res 3 (SMM/UVSP) bright regions relative red-shifted. dark region relative blue-shifted. Athay et al. (1983): C IV with res 3 (SMM/UVSP) no correlation found between doppler shifts and intensity. Dere et al. (1984): C IV with res 1.2 (HRTS) no correlation found between doppler shifts and intensity. Peter (1999): with res 1 (SUMER/SOHO) bright areas are redshifted in C IV. No correlation in Ne VIII. Hassler et al. (1999): Ne VIII with res 1 (SUMER/SOHO) strong outflow occurs along QS lanes. Wilhelm (2): Ne VIII with res 1 (SUMER/SOHO) strongest blueshift appears in the dark region.
5 Outflow vs. Network Outflow vs. Intensity from the position of the outflow from the correlation with the intensity Hassler et al. (1999): Strong outflow (blueshift) occurs along QS lanes especially where lanes come together. Wilhelm (2): Strongest blueshift appears in the dark region in Ne VIII line intensity.
6 Outflow vs. Network Outflow vs. Intensity from the position of the outflow from the correlation with the intensity Hassler et al. (1999): Strong outflow (blueshift) occurs along QS lanes especially where lanes come together. network defined per hand? Wilhelm (2): Strongest blueshift appears in the dark region in Ne VIII line intensity.
7 Outflow vs. Network Outflow vs. Intensity from the position of the outflow from the correlation with the intensity Hassler et al. (1999): Strong outflow (blueshift) occurs along QS lanes especially where lanes come together. network defined per hand? Wilhelm (2): Strongest blueshift appears in the dark region in Ne VIII line intensity. maybe better ways than contour plots?
8 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
9 Observations Date: March 7, 1997 Solar Region: ECH & QS Emission line: Ne VIII(77.428Å) Step size: 1. Date: September 21, 1996 Solar Region: PCH & QS Emission line: Ne VIII(77.428Å) Step size: 3.
10 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
11 Median filtering What do we want: Reveal the cellular pattern of supergranulations. Remove strong local brightenings. Easy to do. using MEDIAN function from IDL. Keep the transition between network and internetwork. Keep the lognormal distribution of the images. Exact Method: Aiouaz, Peter, Lemaire A&A 25 coordinate Y [arcsec] coordinate Y [arcsec] continuum [count] coordinate X [arcsec] filtered continuum coordinate X [arcsec]
12 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
13 What are the tools needed? continuum [count] 1 1 filtered continuum Continuum image: coordinate Y [arcsec] coordinate Y [arcsec] coordinate X [arcsec] intensity [count] coordinate X [arcsec] doppler shift [km/s] Low corona line : Ne VIII coordinate Y [arcsec] coordinate Y [arcsec] coordinate X [arcsec] On the outflow at coronal heights coordinate or thex way [arcsec] I learned to listen to Philippe
14 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
15 Outflow vs. chromospheric network Ne VIII line shift [km/s] Equatorial region 4 a = 6.3 a = Polar region a = Quiet sun part 8 Quiet sun part Filtered continuum intensity: log ( I filt.cont. / < I filt.cont. > ) Hassler,1999: Strong outflow (blueshift) occurs along network lanes. Outflow (blueshift) increases within the network. Aiouaz,25: show blueshift increasing with increasing filtered continuum intensity. Aiouaz,25: In high intensity range: Decrease of the blueshift with increasing filtered continuum intensity. No maximum outflow at network center but rather a network boundaries.
16 Outflow vs. line intensity Ne VIII line shift [km/s] Equatorial region Polar region 4 4 a = 21.8 a = 2.7 a = Coronal hole part 8 Coronal hole part Ne VIII line intensity: log ( I Ne VIII / < I Ne VIII > ) Wilhelm, 2: Strongest blueshift appears in the dark region in Ne VIII intensity. Outflow energy goes to radiation Energy balance Aiouaz, 25: Show blueshift decreasing with Ne VIII line intensity. Aiouaz, 25: In low Ne VIII line intensity range: Increase of the blueshift with increasing line intensity. Less outflow and less radiation Another regime for the Energy balance: Lack of heating.
17 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
18 Relation to the magnetic field log of relative intensity log of filtered continuum magnetic field [gauss] coordinate Y [arcsec] coordinate Y [arcsec] coordinate Y [arcsec] coordinate X [arcsec] Outflow vs. network Maximum outflow not at network center, rather at network boundaries. Regions of maximum blueshift well correlated to the magnetic field concentration coordinate X [arcsec] coordinate X [arcsec] Outflow vs. intensity No magnetic field concentration in regions of very low intensities: seems to confirm the lack of energy. For very low intensities: not enough energy to either accelerate the solar wind or to create any detectable radiation.
19 Outline 1 Previous works 2 Observations 3 Highlight the network 4 Tools needed 5 Results 6 Relation to the magnetic field 7 Summary and Future plans
20 Summary Summary Outflow stronger in the network than in the internetwork. More plasma acceleration (wind): less radiation. Lack of heating: no radiation, no acceleration Maximum blueshift not at the network center: Higher activity at network boundaries? Funnel outflows? Future plans Coronal vs. Transition region lines. Quiet Sun vs. Coronal Holes.
21 Bibliography Athay, R. G., Gurman, J. B., Henze, W., & Shine, R. A. 1983, Astrophysical Journal,, 265, 519 Dere, K. P., Bartoe, J.-D. F., & Brueckner, G. E. 1984, Astrophysical Journal,, 281, 87 Gebbie, K. B., Hill, F., November, L. J., et al. 1981, Astrophysical Journal, 251, L115 Hassler, D. M., Dammasch, I. E., Lemaire, P., et al. 1999, Science, 283, 81 Peter, H. 1999, Astrophysical Journal, 516, 49 Wilhelm, K. 2, Astronomy and Astrophysics, 36, 351
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