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PRELIMINARY RESULTS OF SIMULATION OF A SAWTOOTH CRASH IN CDXU D. D. Schnack and S. E. Kruger Center for Energy and Space Science Science Applications International.

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Presentation on theme: "PRELIMINARY RESULTS OF SIMULATION OF A SAWTOOTH CRASH IN CDXU D. D. Schnack and S. E. Kruger Center for Energy and Space Science Science Applications International."— Presentation transcript:

1 PRELIMINARY RESULTS OF SIMULATION OF A SAWTOOTH CRASH IN CDXU D. D. Schnack and S. E. Kruger Center for Energy and Space Science Science Applications International Corp. San Diego, CA 92121

2 CDXU EQUILIBRIUM Computed by TSC R/a = 1.39 B 0 = 0.127 T I = 58.2 kA I/aB = 1.888 q 0 = 0.605 q max = 8.322  = 7.8 X 10 -3  N = 0.412  A = 4.5 X 10 -7 sec S = 10 4 Pr = 1

3 NIMROD GRID 20 X 12 Bi-quartic finite elements n = 0 - 5  t = 5 X 10 -7 sec ~  A Adiabatic pressure Density profile from equilibrium Run with single processor on 2 GHz Linux workstation

4 LINEAR STABILITY Both n = 1 (~ 1/1) and n = 3 (~ 2/3) linearly unstable

5 n = 1 EIGENFUNCTION Dominant 1/1 structure (“sawtooth mode”) Higher m harmonics  = 2.39 X 10 5 sec -1  A = 0.11 Poloidal FlowToroidal Current Density

6 n = 3 EIGENFUNCTION Dominant 2/3 mode Resonant because q 0 = 0.6 < 2/3  = 1.39 X 10 5 sec -1  A = 0.062 Poloidal Flow Toroidal Current Density

7 NONLINEAR CALCULATION Modal magnetic energy vs. time

8 FIELD LINES t = 10 -4 sec

9 FIELD LINES t = 1.26 X 10 -4 sec

10 FIELD LINES t = 1.32 X 10 -4 sec

11 FIELD LINES t = 1.35 X 10 -4 sec

12 FIELD LINES t = 1.36 X 10 -4 sec

13 COMMENTS All results are preliminary Linear results converged in  t, not tested in  x Large resistivity and viscosity allow runs to be completed on Linux work station Detailed comparisons with M3D required –Linear stability –Nonlinear time scales –Saturation amplitude? –Stochasticity

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