Документ взят из кэша поисковой машины. Адрес
оригинального документа
: http://star.arm.ac.uk/highlights/2012/609.html
Дата изменения: Tue Jul 17 14:58:40 2012 Дата индексирования: Tue Oct 2 03:18:53 2012 Кодировка: Поисковые слова: п п п п п п п п п п п п п п п п п |
G. Tsiropoula, K. Tziotziou, I. Kontogiannis, M. Madjarska, J.G. Doyle, Y. Suematsu
Fig. 1 A SOHO/MDI magnetogram. The boundaries of supergranule cells are marked in yellow, and arrows indicate the supergranular flow pattern (Credits SoHO/MDI).
Abstract
Over the last two decades the uninterrupted, high resolution observations of the Sun, from the excellent range of telescopes aboard many spacecraft complemented with observations from sophisticated ground-based telescopes have opened up a new world producing significantly more complete information on the physical conditions of the solar atmosphere than before. The interface between the lower solar atmosphere where energy is generated by subsurface convection and the corona comprises the chromosphere, which is dominated by jet-like, dynamic structures, called mottles when found in quiet regions, fibrils when found in active regions and spicules when observed at the solar limb. Recently, space observations with Hinode have led to the suggestion that there should exist two different types of spicules called Type I and Type II which have different properties. Ground-based observations in the Ca II H and K filtergrams reveal the existence of long, thin emission features called straws in observations close to the limb, and a class of short-lived events called rapid blue-shifted excursions characterized by large Doppler shifts that appear only in the blue wing of the Ca II infrared line. It has been suggested that the key to understanding how the solar plasma is accelerated and heated may well be found in the studies of these jet-like, dynamic events. However, while these structures are observed and studied for more than 130 years in the visible, but also in the UV and EUV emission lines and continua, there are still many questions to be answered. Thus, despite their importance and a multitude of observations performed and theoretical models proposed, questions regarding their origin, how they are formed, their physical parameters, their association with the underlying photospheric magnetic field, how they appear in the different spectral lines, and the interrelationship between structures observed in quiet and active regions on the disk and at the limb, as well as their role in global processes has not yet received definitive answers. In addition, how they affect the coronal heating and solar wind need to be further explored. In this review we present observations and physical properties of small-scale jet-like chromospheric events observed in active and quiet regions, on the disk and at the limb and discuss their interrelationship.
Last Revised: 2012 July 17th |