Field Reversed Configurations

1. Confinement of Energetic Fusion Particles in FRC ReactorsH. E. Ferrari and R. FarengoCentro Atómico Bariloche and Instituto Balseiro, 8400 Bariloche, RN, Argentina

2. Field Reversed Configurations • Elongated compact toroids with negligible toroidal field. • Very high b (b~1), could use advanced fuels (i. e. D-He3) • Formation: Field reversed q-pinch Rotating magnetic fields (RMF) Spheromak merging • Sustainment: Fusion born charged particles Rotating magnetic fields (RMF) Neutral beam injection

3. This work • Study the dynamics of protons and a particles in D-He3 and D-T FRC reactors. • Calculate the power deposited on each species and the current generated. • Monte Carlo code follows the exact particle trajectories (no gyro-averaging) including stopping and difussion: • Equilibrium (fixed), from Grad-Shafranov equation:

4. D-He3 FRC reactor Equilibrium parameters from ARTEMIS proposal: rs=1.12 m, ℓs=17 m, Te=Ti=87.5 keV, fD=0.5, fHe=0.25

5. Proton orbits

6. Proton orbits • There are more “positive” than “negative” current particles. • With collisions “negative” current particles are lost sooner. • Hollow equilibria have a larger fraction of negative current particles.

7. Effect of difussion • It has been argued that velocity space diffusion should not be important due to the high energy of the protons. • Adding diffusion increases the size of the accessible region and negative current particles get lost rapidly.

8. Current and deposited power • Significant proton current, similar to the proposed value. • Protons deposit their power on the electrons, a particles on the ions. • The equilibrium with the highest fusion power has the lowest current and deposited power. • Poor proton confinement results in high required tE.

9. Current and deposited power Proton power a particle power Proton current

10. Effect of external toroidal field • Can a toroidal field improve proton confinement? • Studied the effect of a “vacuum” toroidal field. • Sharp drop in current and deposited power at low toroidal field due to increased losses through the ends. • At high toroidal field deposited power increases but current decreases.

11. Effect of a rotating magnetic field • A transverse RMF, used to drive current, can degrade particle confinement. • The RMF is characterized by its amplitude, frequency and penetration depth (d=0.1 rs). Proton power Proton current Proton current and deposited power decrease but there are no sharp resonances as in NBI.

12. D-T reactor • Small, recently proposed low fusion power reactor EM: magnetic mirrors added to reduce axial particle losses. The a particle orbits present similar features as those shown for protons but their mean free path is shorter.

13. a-particle orbits

14. Current and deposited power • Large fraction of power deposited but small current. • Power deposited mostly on electrons (4:1). • Increasing the density, and magnetic field, increases the fraction of power deposited in the plasma. • Adding magnetic mirrors increases the fraction of deposited power.

15. Spatial distribution of deposited a particle power

16. Neutral Beam Injection • Particle sources replaced by NB. • Ionization package added to the code. • Beam ions can rotate in the same sense as the current, or in the opposite, depending on the position and velocity they have when ionize (Pq). • Very low efficiency for the D-He3 reactor at reasonable energies (Eb≤2 MeV). • Good efficiency for D-T reactor, ~128 kA/A at 1 MeV.

17. Beam ion orbits “Positive” “Negative”

18. Efficiency for D-T Reactor