On build-up of magnetic energy in the solar atmosphere.
Abstract
The dynamic response of the solar atmosphere is examined with the use of self-consistent numerical solutions of the complete set of nonlinear, two-dimensional, hydromagnetic equations. Of particular interest are the magnetic energy build-up and the velocity field established by emerging flux at the base of an existing magnetic loop structure in a stationary atmosphere. For a plasma with a relatively low beta (β = 0.03) the magnetic energy build-up is approximately twice that of the kinetic energy, while the build-up in magnetic energy first exceeds but is eventually overtaken by the kinetic energy for a plasma with an intermediate beta (β = 3). The increased magnetic flux causes the plasma to flow upward near the loop center and downward near the loop edges for the low beta plasma. The plasma eventually flows downward throughout the lower portion of the loop carrying the magnetic field with it for the intermediate beta plasma. It is hypothesized that this latter case, and possibly the other case as well, may provide a reasonable simulation of the disappearance of prominences by flowing down into the chromosphere (a form of disparition brusque).
- Publication:
-
Solar Physics
- Pub Date:
- March 1976
- DOI:
- 10.1007/BF00152256
- Bibcode:
- 1976SoPh...47..193N
- Keywords:
-
- Energy Storage;
- Kinetic Energy;
- Magnetohydrodynamic Flow;
- Solar Atmosphere;
- Solar Magnetic Field;
- Chromosphere;
- Dynamic Response;
- Flow Velocity;
- Magnetic Flux;
- Self Consistent Fields;
- Solar Prominences;
- Velocity Distribution;
- Solar Physics;
- Magnetic Field;
- Kinetic Energy;
- Velocity Field;
- Dynamic Response;
- Stationary Atmosphere