Microwave Observations of the Sun with Virac RT-32 Radio Telescope: The Expansion of Possibilities

1. Nikulin, I. F., & Dumin, Y. V. (2016). Coronal Partings. Advances in Space Research, 57 (3), 904–911.10.1016/j.asr.2015.11.020 Search in Google Scholar

2. Antiochos, S.K., Mikic, Z., Titov, V.S., Lionello, R., & Linker, J. A. (2011). A Model of the Sources of the Slow Solar Wind. The Astrophysical Journal, 731 (2), 1–28.10.1088/0004-637X/731/2/112 Search in Google Scholar

3. Bezrukovs, D.A., & Ryabov, B.I. (2014). Persistence of Relatively Low Plasma Density in the Atmosphere of Sun Spot. Latvian Journal of Physics and Technical Sciences, 51 (2), 65–72. Search in Google Scholar

4. Ryabov, B., Bezrukovs, D., & Kallunki, J. (2017). Low Brightness Temperature in Microwaves at Periphery of Some Solar Active Regions. Latvian Journal of Physics and Technical Sciences, 54 (3), 58–66.10.1515/lpts-2017-0021 Search in Google Scholar

5. Bezrukovs, D. (2013). Spectral Polarimetric Observations of the Sun by VIRAC RT-32 Radio Telescope: First Results. Baltic Astronomy, 22 (1), 9–13.10.1515/astro-2017-0142 Search in Google Scholar

6. Bezrukovs, D., Kallunki, J., & Ryabov, B. (2018) Spectral Polarimetric Observations of the Sun by VIRAC RT-32 Radio Telescope: Calibrations. Space Research Review, 5, 1–16. Search in Google Scholar

7. Borovik, V.N., Kurbanov, M.S., Livshits, M.A., & Ryabovy, B.I. (1990). Coronal Holes against the Background of the Quiet Sun: Observations with the RATAN-600 in the 2–32 cm Range. Astron. J., 67, 1038–1052. Search in Google Scholar

8. Ryabov, B.I., & Shibasaki, K. (2016). Depressed Emission between Magnetic Arcades near Sunspot. Baltic Astronomy, 25 (2), 252.10.1515/astro-2017-0124 Search in Google Scholar

9. Kallunki, J. (2018). Rotation of the Low Temperature regions (LTR) at 8 mm. Phys. Astron. Int. J., 2 (5), 403–406.10.15406/paij.2018.02.00117 Search in Google Scholar

10. Braiša, R., Ruždjak, V., Vršnak, B., Wohl, H., Pohjolainen, S., & Urpo, S. (1999). An Estimate of Microwave Low-Brightness-Temperature Regions Obtained Measuring their Rotation Velocity. Solar Physics, 184, 281–296.10.1023/A:1005124022163 Search in Google Scholar

11. Mangum, J.G., Emerson, D.T., & Greisen, E.W. (2007). The On-The-Fly Imaging Technique, A&A, 474, 679–687.10.1051/0004-6361:20077811 Search in Google Scholar

12. White, R. L. (1994). Image Restoration Using the Damped Richardson-Lucy Method. Astronomical Data Analysis Software and System III, ASP Conference Series, 61.10.1117/12.176819 Search in Google Scholar

13. Grebinskij, A., Shibasaki, K., & Zhang, H. (1998). Microwave Measurements of the Solar Magnetic Fields at Chromosphere-Corona. Solar Physics with Radio Observations, Proceedings of Nobeyama Symposium, NRO report 479, 59–64. Search in Google Scholar

14. Bezrukov, D. A., Ryabov, B. I., Bogod, V. M., Gelfreikh, G. B., Maksimov, V. P., Drago, F., … & Borisevich, T. P. (2005). On the Technique of Coronal Magnetography through Quasi-Transverse Propagation of Microwaves. Baltic Astronomy, 14 (1), 83–103. Search in Google Scholar

15. Obridko, V.N., & Staude, J. (1988). A Two-Component Working Model for the Atmosphere of a Large Sunspot Umbra. Astron. Astrophys., 189, 232–242. Search in Google Scholar