| Issue |
A&A
Volume 516, June-July 2010
|
|
|---|---|---|
| Article Number | L5 | |
| Number of page(s) | 5 | |
| Section | Letters | |
| DOI | https://doi.org/10.1051/0004-6361/201014786 | |
| Published online | 22 June 2010 | |
Letter to the Editor
Magnetic tension of sunspot fine structures*
Udaipur Solar Observatory, Physical Research Laboratory,
Dewali, Bari Road, Udaipur-313 001, India e-mail: [pvk;stiwari]@prl.res.in
Received:
14
April
2010
Accepted:
20
May
2010
Context. The equilibrium structure of sunspots depends critically on its magnetic topology and is dominated by magnetic forces. Tension force is one component of the Lorentz force, which balances the gradient of magnetic pressure in force-free configurations.
Aims. We employ the tension term of the Lorentz force to clarify the structure of sunspot features like penumbral filaments, umbral light bridges, and outer penumbral fine structures.
Methods. We computed the vertical component of the tension term of Lorentz force over two active regions, NOAA AR 10933 and NOAA AR 10930 observed on 5 January 2007 and 12 December 2006, respectively. The former is a simple active region while the latter is a complex one with highly sheared polarity inversion line (PIL). We obtained the vector magnetograms from Hinode(SOT/SP).
Results. We find an inhomogeneous distribution of tension with both positive and negative signs in various features of the sunspots. The existence of positive tension at locations of lower field strength and higher inclination is compatible with the uncombed model of the penumbral structure. Positive tension is also seen in umbral light bridges, which could be indication of uncombed structure of the light bridge. Likewise, the upwardly directed tension associated with bipolar regions in the penumbra could be a direct confirmation of the sea serpent model of penumbral structures. Upwardly directed tension at the PIL of AR 10930 seems to be related to flux emergence. The magnitude of the tension force is greater than the force of gravity in some places, implying a nearly force-free configuration for these sunspot features.
Conclusions. From our study, magnetic tension emerges as a useful diagnostic of the local equilibrium of the sunspot fine structures.
Key words: Sun: photosphere / sunspots / magnetic fields
Figures A.1–A.3 are only available in electronic form at http://www.aanda.org
© ESO, 2010
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