modeling beam ion relaxation with application to diii-d
DESCRIPTION
Modeling Beam Ion Relaxation with application to DIII-D. K.Ghantous , N.N. Gorelenkov PPPL, 2012. TAE I nduced Losses of EP. Illustration of self consistent QL relaxation. QL model. where. where. instability. diffusion. Saturation at marginal stability. the mode number, n - PowerPoint PPT PresentationTRANSCRIPT
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Modeling Beam Ion Relaxation with application to DIII-D
K.Ghantous, N.N. GorelenkovPPPL, 2012
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TAE Induced Losses of EP
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QL model
where
where
instability
Saturation at marginal stability
diffusion
Illustration of self consistent QL relaxation
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Using analytic expressions for finding the qualitative dependencies of the growth and damping rates on energetic particle’s
The mode that are most unstable form a plateau1 in n number where
the mode number, nrelative mode widths to particle orbitPlasma parametersIsotropy
Which is used to compute the critical conditions on the slope of the pressure profiles at each radial position r0.
1Fu, Phys. Fluids B 4 (1992) 3722;
Reduced QL model
i.e
Kolesnichenko’s rough estimate for the percentage of particles that are resonant is h
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Integrating relaxed profiles.
With the constraints:
continuity Particle conservation
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NOVA and NOVA-KTo apply 1.5D on experimental results, NOVA and NOVA-K are used to give quantitative accuracy to the analytically computed profiles.
We find the two most localized modes from NOVA for a given n close to the expected values at the plateau.
We calculate the damping and maximum growth rate at the two locations, r1 and r2, to which the analytic rates are calibrated to by multiplying them by the following factor, g(r) .
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DIII-D beam losses and TAE activity
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NOVA Computed rates of discharge #142111
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Normalized rates for t=575 ms
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1.5D results