Astronomy and Astrophysics – Astronomy
Scientific paper
Apr 2001
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2001apj...550.1051s&link_type=abstract
The Astrophysical Journal, Volume 550, Issue 2, pp. 1051-1063.
Astronomy and Astrophysics
Astronomy
21
Hydrodynamics, Sun: Flares, Sun: X-Rays, Gamma Rays
Scientific paper
We present results of one-dimensional hydrodynamic simulations of the chromospheric evaporation produced by a microflare in a large-scale loop as a model of X-ray jets. The initial conditions of the simulations are based on the observations of X-ray jets. We deposit thermal energy (~1×1028 ergs) in the corona. The deposited energy is rapidly transported to the chromosphere by conduction, which heats the dense plasma in the upper chromosphere. As a result, the gas pressure is increased and drives a strong upflow of dense, hot plasma along the magnetic loop. We found the following features of evaporation in the results of our simulations: (1) the maximum temperature of the evaporating plasma is determined by the balance between the conductive flux and the heating flux; (2) the total mass of evaporating plasma is controlled by the balance between the conductive flux and enthalpy flux; (3) the relationship between the density neva, height of energy deposition sflare, and heating rate Fh is described as neva~F4/7h/s3/7flare (4) the X-ray intensity along the evaporation-flow plasma decreases exponentially with distance from the footpoint, and that exponential intensity distribution holds from the early phase to the decay phase; (5) in the single-loop model, the temperature decreases with distance from the energy deposition site (on the other hand, a hot region is present in front of the evaporation front in the multiple-loop model); (6) we compare the physical parameters of the evaporation flow with the observations of the X-ray jet that occurred on 1992 September 3 and find that the physical parameters of evaporating plasma are similar to those of the Yohkoh-observed X-ray jet. Since these properties of the evaporation flow are similar to the observed properties of X-ray jets, we suggest that an X-ray jet is the evaporation flow produced by a flare near the footpoint of a large-scale loop. Furthermore, according to the X-ray intensity distribution along the evaporation flow, we suggest that a multiple-loop model based on the magnetic reconnection mechanism can reproduce the properties of an X-ray jet better than the single-loop model.
Hori Kuniko
Shibata Kazunari
Shimojo Masumi
Yokoyama Takaaki
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