| 1 | = ISSDE Basic Theory |
| 2 | == ISSDE Reference |
| 3 | * [https://iopscience.iop.org/article/10.1088/1674-1056/abefc7 ISSDE program] |
| 4 | * [https://iopscience.iop.org/article/10.1088/1674-1056/ac5883/meta Fast ion loss in EAST] |
| 5 | * [https://iopscience.iop.org/article/10.1088/1741-4326/acbdad ICRF-NBI synergy produced fast ion loss] |
| 6 | == ISSDE Basic Algorithm |
| 7 | * Splitting Method |
| 8 | * Volumn-preserving algorithm |
| 9 | * Quasi-Newton Method |
| 10 | == Physical Process Calculated by ISSDE |
| 11 | * Fast ion trajectory |
| 12 | * Electron-Electron collision |
| 13 | * Electron-Ion collision |
| 14 | * Ion-Ion collision |
| 15 | * Fast ion trajectory in Tokamak |
| 16 | * Fast ion loss under the effect of ripple field, MHD perturbation field, TBM field and collision |
| 17 | * Fast ion loss with LCFS boundary, first wall and limiters |
| 18 | * Slowing down process in Tokamak |
| 19 | * Evolution of fast ion distribution |
| 20 | * Heat load on first wall and limiters |
| 21 | * Devices can be calculated |
| 22 | * EAST |
| 23 | * CFETR |
| 24 | * BEST |
| 25 | * CFEDR |
| 26 | == ISSDE Interview Setting |
| 27 | * EFIT provides the equilibrium field |
| 28 | * NUBEAM provides the initial distribution of fast ion |
| 29 | * ANSYS provides TBM field |
| 30 | * Analysis solution provide perturbation field |
| 31 | * ANSYS provides ripple field |
| 32 | * Analysis solution provide ripple field |
| 33 | * Analysis solution provide MHD perturbation field |
| 34 | * Engineering data for first wall and limiters |
| 35 | * TORIC provide ICRF field |