Institute of Theoretical Astrophysics, University of Oslo, Norway.
Philos Trans A Math Phys Eng Sci. 2012 Jul 13;370(1970):3129-50. doi: 10.1098/rsta.2011.0537.
The overall structure and the fine structure of the solar photosphere outside active regions are largely understood, except possibly the important roles of a turbulent near-surface dynamo at its bottom, internal gravity waves at its top and small-scale vorticity. Classical one-dimensional static radiation-escape modelling has been replaced by three-dimensional time-dependent magento-hydrodynamic simulations that come closer to reality. The solar chromosphere, in contrast, remains little understood, although its pivotal role in coronal mass and energy loading makes it a principal research area. Its fine structure defines its overall structure, so that hard-to-observe and hard-to-model small-scale dynamical processes are key to understanding. However, both chromospheric observation and chromospheric simulation presently mature towards the required sophistication. Open-field features seem of greater interest than easier-to-see closed-field features.
除了可能在底部存在一个动荡的近表面发电机、在顶部存在内部重力波以及存在小尺度涡度之外,太阳色球层的整体结构和精细结构仍然知之甚少,尽管其在日冕物质和能量加载中的关键作用使其成为主要研究领域。尽管其精细结构定义了其整体结构,因此难以观测和建模的小规模动力过程是理解的关键,但太阳色球层仍然知之甚少。相比之下,易于观察的闭磁场特征,开磁场特征似乎更有趣。虽然经典的一维静态辐射逃逸模型已经被更接近现实的三维时变磁流体动力学模拟所取代,但太阳色球层仍然知之甚少。