Abstract
Analysis of spectropolarimetric observations of two circular sunspots located close to disk centre in H\({\alpha }\) (6562.8 Å) and Fe i (6569.22 Å) is presented in this paper. The corresponding active region numbers are NOAA 10940 and NOAA 10941 referred to as AR1 and AR2, respectively. The vector magnetic field at the photosphere is derived through inversion of Stokes profiles of Fe i under Milne–Eddington atmospheric model. The chromospheric vector magnetic field is derived from H\({\alpha }\) Stokes profiles under weak-field approximation. Azimuthally averaged magnetic field as a function of radial distance from the centre of sunspot at the photosphere and chromosphere are studied. At the photosphere, the radial variation shows a well known behaviour that the total field and the line-of-sight (LOS) component monotonically decrease from centre to the edge of the sunspot and the transverse component initially increases, reaches a maximum close to half the sunspot radius and then decreases. LOS and the transverse components become equal close to half the sunspot radius consistent with the earlier findings. At the chromosphere, all the components of the magnetic field decrease with the sunspot radius. However, the LOS component decreases monotonically whereas the transverse component decreases monotonically up to about 0.6 times the sunspot radius after which it reaches a constant value. Azimuthally averaged magnetic field gradient from photosphere to chromosphere is also presented here.
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References
Abdussamatov H. I. 1971, Solar Phys., 16, 384
Andretta V., Jones H. P. 1997, Astrophys. J., 489, 375
Auer L. H., House L. L., Heasley J. N. 1977, Solar Phys., 55, 47
Balasubramaniam K. S., Christopoulou E. B., Uitenbroek H. 2004, Astrophys. J., 606, 1233
Balasubramaniam K. S., Venkatakrishnan P., Bhattacharyya J. C. 1985, Solar Phys., 99, 333
Balthasar H. 2018, Solar Phys., 293, 120
Bappu M. K. V. 1967, Solar Phys., 1, 151
Bjørgen J. P., Leenaarts J., Rempel M., Cheung M. C. M., Danilovic S., de la Cruz Rodríguez J., Sukhorukov, A. V. 2019, Astron. Astrophys., 631, 33
Borrero J. M., Ichimoto K. 2011, Liv. Rev. Solar Phys., 8, 4
Casini R., Landi Degl’Innocenti E. 1994, Astron. Astrophys., 291, 668
Centeno R. 2018, Astrophys. J., 866, 89
Hanaoka Y. 2005, Pub. Astron. Soc. Japan, 57, 235
Jefferies J. T., Mickey D. L. 1991, Astrophys. J., 372, 694
Joshi J., Lagg A., Hirzberger J., Solanki S. K. 2017, Astron. Astrophys., 604, 98
Kerr G. S., Fletcher L., Russell A. e. J. B., Allred J. C. 2016, Astrophys. J., 827, 101
Kobanov N. I., Makarchik D. V., Sklyar A. A. 2003, Solar Phys., 217, 53
Kuridze D., Henriques V. M. J., Mathioudakis M., Rouppe van der Voort L., de la Cruz Rodríguez J., Carlsson M. 2018, Astrophys. J., 860, 10
Lagg A., Lites B., Harvey J., Gosain S., Centeno R. 2017, Space Sci. Rev., 210, 37
Landi Degl’Innocenti E., Landi Degl’Innocenti M. 1973, Solar Phys., 31, 299
Landi Degl’Innocenti E., Landolfi M. 2004, Polarization in Spectral Lines, Astrophysics and Space Library, Volume 307, Kluwer Academic Publishers, Dordrecht
Leenaarts J., Carlsson M., Rouppe van der Voort L. 2012, Astrophys. J., 749, 136
Lites B. W., Skumanich A. 1990, Astrophys. J., 348, 747
López Ariste A., Casini R., Paletou F. et al. 2005, Astrophys. J. Lett., 621, L145
Martínez González M. J., Bellot Rubio L. R. 2009, Astrophys. J., 700, 1391
Nagaraju K., Ramesh K. B., Sankarasubramanian K., Rangarajan K. E. 2007, Bull. Astro. Soc. India, 35, 307
Nagaraju K., Sankarasubramanian K., Rangarajan K. E. 2008a, Astrophys. J., 678, 531
Nagaraju K., Sankarasubramanian K., Rangarajan K. E., Ramesh K. B., Singh J., Devendran P., Hariharan 2008b, Bull. Astro. Soc. India, 36, 99
Orozco Suarez D., Lagg A., Solanki S. K. 2005, in Innes D. E., Lagg A., Solanki S. K., eds, Chromospheric and Coronal Magnetic Fields, ESA Special Publication 596, p. 59
Rutten R. J. 2007, in Heinzel P., Dorotovič I., Rutten R. J., eds, The Physics of Chromospheric Plasmas, ASP Conference Series, Volume 368, p. 27
Rutten R. J. 2008, in Matthews S. A., Davis J. M., Harra L. K., eds, First Results from Hinode, ASP Conference Series, Volume 397, p. 54
Sanchez Almeida J., Lites B. W. 1992, Astrophys. J., 398, 359
Sankarasubramanian K., Srinivasulu G., Ananth A. V., Venkatakrishnan P. 2000, J. Astrophys. Astron. 21, 241
Schlichenmaier R., Collados M. 2002, Astron. Astrophys., 381, 668
Skumanich A., Lites B. W. 1987, Astrophys. J., 322, 473
Socas-Navarro H. 2001, in Sigwarth M., ed., Advanced Solar Polarimetry—Theory, Observation and Instrumentation, PASP, 236, 487
Socas-Navarro H., Uitenbroek H. 2004, Astrophys. J. Lett., 603, L129
Uitenbroek H. 2006, in Leibacher J., Stein R. F., Uitenbroek H., eds, Solar MHD Theory and Observations: A High Spatial Resolution Perspective, PASP, 354, 313
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We thank the observers Devendran and Hariharan for their help during observations.
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Nagaraju, K., Sankarasubramanian, K. & Rangarajan, K.E. H\(\alpha \) full line spectropolarimetry as diagnostics of chromospheric magnetic field. J Astrophys Astron 41, 10 (2020). https://doi.org/10.1007/s12036-020-9627-9
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DOI: https://doi.org/10.1007/s12036-020-9627-9