Study of solar brightness profiles in the 18–26 GHz frequency range with INAF radio telescopes

Context. The Sun is an extraordinary workbench, on which several fundamental astronomical parameters can be measured with high precision. Among these parameters, the solar radius R⊙ plays an important role in several aspects, for instance, in evolutionary models. Moreover, it conveys information abo...

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Published in:Astronomy and astrophysics (Berlin) 2024-04, Vol.684
Main Authors: Marongiu, M, Pellizzoni, A, Mulas, S, Righini, S, Nesti, R, Murtas, G, Egron, E, Iacolina, M N, Melis, A, Valente, G, Serra, G, Guglielmino, S L, Zanichelli, A, Romano, P, Loru, S, Bachetti, M, Bemporad, A, Buffa, F, Concu, R, Deiana, G L, Karakotia, C, Ladu, A, Maccaferri, A, Marongiu, P, Messerotti, M, Navarrini, A, Orfei, A, Ortu, P, Pili, M, Pisanu, T, Pupillo, G, Saba, A, Schirru, L, Tiburzi, C, Zucca, P
Format: Article
Language:English
Subjects:
Antennas
Atmospheric models
Beams (radiation)
Celestial bodies
Correlation analysis
Correlation coefficients
Errors
Frequency ranges
Mathematical models
Parameters
Prolateness
Radio frequency
Radio telescopes
Solar activity
Solar cycle
Solar interior
Solar limb
Telescopes
Two dimensional models
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Summary:Context. The Sun is an extraordinary workbench, on which several fundamental astronomical parameters can be measured with high precision. Among these parameters, the solar radius R⊙ plays an important role in several aspects, for instance, in evolutionary models. Moreover, it conveys information about the structure of the different layers that compose the solar interior and its atmosphere. Despite the efforts to obtain accurate measurements of R⊙, the subject is still debated, and measurements are puzzling and/or lacking in many frequency ranges. Aims. We determine the mean, equatorial, and polar radii of the Sun (Rc, Req, and Rpol) in the frequency range 18.1 − 26.1 GHz. We employed single-dish observations from the newly appointed Medicina Gavril Grueff Radio Telescope and the Sardinia Radio Telescope (SRT) in five years, from 2018 to mid-2023, in the framework of the SunDish project for solar monitoring. Methods. Two methods for calculating the radius at radio frequencies were employed and compared: the half-power, and the inflection point. To assess the quality of our radius determinations, we also analysed the possible degrading effects of the antenna beam pattern on our solar maps using two 2D models (ECB and 2GECB). We carried out a correlation analysis with the evolution of the solar cycle by calculating Pearson’s correlation coefficient ρ in the 13-month running means. Results. We obtained several values for the solar radius, ranging between 959 and 994 arcsec, and ρ, with typical errors of a few arcseconds. These values constrain the correlation between the solar radius and solar activity, and they allow us to estimate the level of solar prolatness in the centimeter frequency range. Conclusions. Our R⊙ measurements are consistent with the values reported in the literature, and they provide refined estimates in the centimeter range. The results suggest a weak prolateness of the solar limb (Req > Rpol), although Req and Rpol are statistically compatible within 3σ errors. The correlation analysis using the solar images from the Grueff Radio Telescope shows (1) a positive correlation between solar activity and the temporal variation in Rc (and Req) at all observing frequencies, and (2) a weak anti-correlation between the temporal variation of Rpol and solar activity at 25.8 GHz.
ISSN:0004-6361
1432-0746
DOI:10.1051/0004-6361/202348768