توزیع میدان سرعت جریان پلاسما در پایه جت‌های رنگین‌سپهر

نویسندگان

1 دانشجوی کارشناسی ارشد، گروه فیزیک، دانشگاه پیام نور، زنجان، ایران

2 دانشیار، گروه فیزیک، دانشگاه پیام نور، تهران، ایران

3 استادیار، گروه فیزیک، دانشکده علوم پایه، واحد تبریز، دانشگاه آزاد اسلامی، تبریز، ایران

چکیده

خورشید به‌طور مداوم ذرات یونیزه را به بیرون از اتمسفر پرتاب می‌کند که سبب باد‌های خورشیدی می‌شوند. برای درک اینکه منشأ این بادها کجاست 50 سال است که تحقیقات گوناگون در شید‌سپهر، تاج و رنگین‌سپهر انجام می‌شود. حفره‌های تاجی در مقیاس بزرگ معمولاً مناطقی هستند که به‌طور قطعی به‌عنوان منشأ بادهای خورشیدی پذیرفته شده‌اند. با‌این‌حال هنوز تحقیق و پژوهش در مناطق دیگر انجام می‌شود. جت‌های شبکه‌ای یکی ازپدیده‌هایی هستند که به‌عنوان منشأ بادهای خورشیدی مطرح می‌باشند. هدف ما بررسی توزیع میدان سرعت درون آنها و پی بردن  به ساختار این نوع جت‌ها  و نقش آن در جریان‌های پلاسمایی می‌باشد. نوسانات و جابه‌جایی عرضی محور جت‌ها را می‌توان به‌دلیل وجود امواج عرضی در امتداد محور آنها تعبیر نمود. دو نوع موج که مسئول این نوسانات هستند عبارتند از امواج مگنتواکوستیکی و امواج آلفون. در این مقاله با استفاده از تصاویر تلسکوپ  IRISبا کمک الگوریتم FLCT تحت برنامه‌نویسی IDL توزیع میدان سرعت جریان پلاسما را در پایه جت‌های رنگین‌سپهر مورد‌مطالعه قرار دادیم.

کلیدواژه‌ها

موضوعات


عنوان مقاله [English]

Distribution of plasma flow velocity field at the base of chromospheric jets

نویسندگان [English]

  • Elnaz Amirkhanlou 1
  • Ehsan Tavabi 2
  • Sima Zeighami 3
1 M.Sc. Student, Department of Physics, Payame Noor University, zanjan, Iran
2 Associate Professor, Department of Physics, Payame Noor University, Tehran, Iran
3 Assistant Professor, Department of Physics, Tabriz Branch, Islamic Azad University, Tabriz, Iran
چکیده [English]

The sun is constantly throwing ionized particles out of its surface and causing solar storms. Various investigations have been carried out for finding out the origin of these storms for 50 years, in the photosphere, corona, and chromosphere. Large-scale coronal holes are usually areas that are definitely accepted for origin of the storms. However, research is still being done in other areas. Network jets are one of the issues that we have tried to investigate the distribution of their velocity field and their structures and also their role in plasma flows. Oscillations and transverse displacement of the jet axis can be interpreted as the presence of transverse waves along their axis. The two types of waves responsible for these fluctuations are magneto-hydrodynamic waves and alfvenic waves. In this paper, we studied the transverse displacement of the network jet axis, with the FLCT algorithm under IDL. The FLCT method is widely used to obtain the speed of moving features. The observed area is so large that we can identify many of the network jets. After choosing the coordinates of the item using the FLCT algorithm, we intend to obtain the Alfven velocity of the desired coordinates. The FLCT algorithm is a mathematical program used to construct a two-dimensional velocity field of connected images. The calculation of speed in this method depends on three factors: 1. Isolate the point on the image, 2- Calculation of correlation function between two images, 3. Peak location of the mutual correlation function, calculated for each pixel of the velocity. The FLCT algorithm uses interpolation to eliminate the complexity of the fixed angle on the center of the images. In results we can see the images analyzed in the IDL program, using MATLAB software to show the speed vectors that are torsional and indicate the speed of the alphabet. The images are in pixels and each pixel are is 0.3 sec. We estimated the chromosphere mass velocity of about 20 kms-1 using FLCT. Some of the network jets in the images seem to be other than the second type solar spicules sticks. However, we noticed that the speed of the jets is generally twice as large as the second type of sticks, which indicates the high contribution of these jets to the mass and energy of the solar atmosphere. We have noticed that network jets are important regardless of their relationship with second-generation sticks. A bunch of network jets is considered as an example of a jet. The network jet mechanism demonstrates the dynamics of the jets with high speeds (close to the speed of the Alfven in the interface area), which allows magnetic reconnection between the small magnetic rings and the background. Based on observational findings, several theoretical models and numerical simulations have been developed to describe the mechanism of these structures. Of course, unlike the remarkable improvements created by very accurate observations and the expansion of numerical theories and simulations, it is still unclear and their mutual relationship, their physical parameters, the definition of their formation mechanism and their possible role in the solar corona heat is unknown. These ambiguities are mainly due to the difference in the appearance of these phenomena when viewed in a variety of spectral lines.

کلیدواژه‌ها [English]

  • plasma
  • chromospheric jets
  • velocity
  • Alfven waves
Cranmer, S. R., 2010, Incorporating Kinetic Effects into Global Models of the Solar Wind, American Geophysical Union, Fall Meeting 2010, Harvard, USA.
De Pontieu, B., Hansteen,V. H., Rouppe van der Voort, L., van Noort, M. and Carlsson, M., 2011, High-Resolution Observations and Modeling of Dynamic Fibrils, The Astrophysical Journal, 655, 624-641, doi: 10.1086/509070.
De Pontieu, B., McIntosh, S. W., Carlsson, M., Hansteen, V. H., Tarbell, T. D., Schrijver, C. J., Title, A. M., Shine, R. A., Tsuneta, S. and Katsukawa, Y. P., 2007a, Chromospheric Alfvénic Waves Strong Enough to Power the Solar Wind, science, 318, 1574, doi: 10.1126/science.1151747.
Fisher, G. H. and Welsch, B. T., 2008, FLCT: A Fast, Efficient Method for Performing Local Correlation Tracking, Subsurface and Atmospheric Influences on Solar Activity, Astronomical Society of the Pacific Conference Series, proceedings of the conference,. New Mexico, USA.
Martinez-Sykora, .J, De Pontieu, B., McIntosh, S. W., Carlsson, M., Hansteen, V. H., Tarbell, T. D., Boerner, P., Schrijver, C. J. and Title, A. M., 2011, The Origins of Hot Plasma in the Solar Corona, science, 331, 55, doi: 10.1126/science.1197738.
Pereira, T., Tiago, M. D., De Pontieu, B., Carlsson, M., 2012, Quantifying Spicules, The Astrophysical Journal, 759, 16, doi: 10.1088/0004-637X/759/1/18.
Shibata, K., Nakamura, T., Matsumoto, T., Otsuji, K., Okamoto, T. J., Nishizuka, N., Kawate, T., Watanabe, H., Nagata, S., UeNo, S., Kitai, R., Nozawa, S., Tsuneta, S., Suematsu, Y., Ichimoto, K., Shimizu, T., Katsukawa, Y., Tarbell, T. D., Berger, T., E. Lites, B. W., Shine, R. A. and Title, A. M., 2007, Chromospheric Anemone Jets as Evidence of Ubiquitous Reconnection, Science, 318, 1591, doi: 10.1126/science.1146708.
Tavabi, E., Koutchmy, S. and Golub, L., 2015a, Limb Event Brightenings and Fast Ejection Using IRIS Mission Observations. Solar Physics, 290, 2871-2887, doi: 10.1007/s11207-015-0771-3.
Tavabi, E., Koutchmy, S., Ajabshirizadeh, A., Ahangarzadeh Maralani, A. R. and Zeighami, S., 2015b, Alfvenic wave in polar limb spicules, Astronomy and Astrophysics, 573, 7, doi: 10.1051/0004-6361/201423385.
Tian, H., DeLuca, E. E., Cranm, S. R., De Pontieu, B., Peter, H., Martinez-Sykora, J., Golub, L., McKillop, L., Reeves, K. K., Miralles, M. P., McCauley, P., Saar, S., Weber, M., Murphy, N., Lemen, J., Title, A., Boerner, P., Hurlbur, N., Testa, P., Tarbell, T. D., Wuelser, P. J., Kleint, L., Kankelborg, C., Jaeggli, S., Carlsson, M., Hansteen, V. and McIntosh, S. W., 2014, Prevalence of Small-scale Jets from the Networks of the Solar Transition Region and Chromosphere, Science, 346, doi: 10.1126/science.1255711.
Tu, C-Y., Chuan, Yi., Zhou, C., Marsch, E., Xia, L- D., Zhao, L., Wang, J-X. and Wilhelm, K., 2005, Correlation Heights of the Sources of Solar Ultraviolet Emission Lines in a Quiet-Sun Region, The Astrophysical Journal, 624, 133-136, doi: 10.1086/430520.
Welsch, B. T. and Fisher, G. H., Abbett, W. P. and Regnier, S., 2004, Recovering Photospheric Velocities from Magnetograms by Combining the Induction Equation with Local Correlation Tracking, The Astrophysical Journal, 610, 1148-1156, doi: 10.1086/421767.
Yang, L., Zhang, J., Liu, W., Li, T. and Shen, Y., 2013, SDO/AIA and Hinode/EIS Observations of Interaction between an EUV Wave and Active Region Loops, The Astrophysical Journal, 775, 12, doi: 10.1088/0004-637X/775/1/39.
Zeighami, S., Ahangarzadeh Maralani, A. R., Tavabi, E. and Ajabshirizadeh, A., 2016, Evidence of  Energy Supply by Active-Region Spicules to the Solar Atmosphere, Solar Physics, 291, 847–858, doi: 10.1007/s11207-016-0866-5.
http://iris.lmsal.com/operations.html.