Energetics of a double flare on November 8, 1980
Abstract
Here we complete an energy balance analysis of a double impulsive hard X-ray flare. From spatial observations, we deduce both flares probably occur in the same loop within the resolution of the data. For the first flare, the energy in the fast electrons (assuming a thick-target model) is comparable to the convective up-flow energy, suggesting that these are related successive modes of energy storage and transfer. The total energy lost through radiation and conduction, 2.0 × 1028 erg, is comparable to the energy in fast electrons 2.5 × 1028 erg. For the second flare, the energy in the fast electrons is more than one order of magnitude greater than the energy of the convective up-flow. Total energy losses are within a factor of two lower than the calculated fast electron energy. We interpret the observations as showing that the first flare occurred in a small loop with fast electrons heating the chromosphere and resulting in chromospheric evaporation increasing the density in the loop. For the second flare most of the heating occurred at the electron acceleration site. The two symmetrical components of the Ca XIX resonance line and a high velocity down-flow of 115 km s −1 observed at the end of the second hard X-ray burst are consistent with the flare eruption (reconnection) region being high in the flare loop. The estimated altitude of the acceleration site is 5500 km above the photosphere.
- Publication:
-
Solar Physics
- Pub Date:
- July 1985
- DOI:
- 10.1007/BF00177204
- Bibcode:
- 1985SoPh...98..141D
- Keywords:
-
- Energy Budgets;
- High Energy Electrons;
- Solar Flares;
- X Ray Astronomy;
- Astronomical Maps;
- Chromosphere;
- Morphology;
- Solar Electrons;
- Solar X-Rays;
- Solar Physics;
- Flare;
- Fast Electron;
- Electron Acceleration;
- Symmetrical Component;
- Total Energy Loss