Abstract
The evolution of the runaway electron (RE) energy distribution function f(epsilon) during massive gas injection into centered post-disruption runaway electron plateaus has been reconstructed. Overall, f(epsilon) is found to be much more skewed toward low energy than predicted by avalanche theory. The reconstructions also indicate that the RE pitch angle theta is not uniform, but tends to be large at low energies and small theta similar to 0.1-0.2 at high energies. Overall power loss from the RE plateau appears to be dominated by collisions with background free and bound electrons, leading to line radiation. However, the drag on the plasma current appears to be dominated by collisions with impurity ions in most cases. Synchrotron emission appears not to be significant for overall RE energy dissipation but may be important for limiting the peak RE energy. (C) 2015 AIP Publishing LLC.
