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Kinetic Effects on MHD Modes in NSTX

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Title: Kinetic Effects on MHD Modes in NSTX


1
Kinetic Effects on MHD Modes in NSTX
  • C. Z. (Frank) Cheng,
  • N. N. Gorelenkov, G. Kramer, E. Fredrickson
  • Princeton Plasma Physics Laboratory
  • Princeton University
  • Presented at NSTX Results Review/NSTX Research
    Forum

2
Outline
  • Motivation
  • MHD Model Advantage and Limitation
  • Characteristic Scales in NSTX Plasmas
  • Kinetic Stabilization of Ballooning Modes
  • Destabilization of TAEs by Energetic Particles
  • Kinetic-Fluid Model
  • Summary

3
Motivation
  • Multiscale coupling small-scale particle kinetic
    physics couples with large-scale MHD phenomena.
  • Energetic particle physics global instabilities
    (TAE and fishbone modes) are driven by fast ions
    via wave-particle interaction and can cause
    serious fast ion loss in toroidal plasmas.
  • Disparate scales in plasmas traditionally
    global-scale phenomena are studied using MHD or
    multi-fluid models, while small-scale phenomena
    are described by kinetic theories.
  • Kinetic-MHD model and simulation codes through
    joint theory-experimental studies, understanding
    of energetic particle physics phenomena in major
    tokamak experiments has improved.
  • Thermal particle kinetic physics thermal
    particle kinetic effects are as important as fast
    ions in determining global phenomena in burning
    plasmas e.g., kinetic ballooning modes, TAEs,
  • ? Need to include kinetic effects of both fast
    and thermal particles in studying MHD phenomena
    in NSTX.

4
Global Phenomena MHD Model
  • Momentum Equation
  • r / t Vr V rP J B
  • Continuity Equation
  • / t Vr r rrV 0
  • Maxwell's Equations
  • B/ t rE, J rB , rB 0
  • Ohm's Law E VB ?J
  • Adiabatic Pressure Law / t Vr (P/r5/3)
    0
  • ? important to understand advantages and
    limitations of MHD model.

5
Advantages of MHD Model
  • Retains properly global geometrical effects such
    as pressure gradient, magnetic field gradient
    curvature.
  • Covers most long wavelength, low-frequency EM
    waves and instabilities
  • -- Fast Magnetosonic branch (w ' kVA)
    compressional Alfven waves (CAEs), mirror modes,
    etc.
  • -- Shear Alfven branch (w kVA) shear
    Alfven waves (TAEs, GAEs), ballooning modes,
    kink modes, tearing modes, etc.
  • -- slow magnetosonic modes (w kCs)
  • Simpler to perform theoretical analysis and
    simulations than gyrokinetic/Vlasov models.

6
Limitations of MHD Model
  • Ohm's law for small resistivity, plasma fluid is
    almost frozen in B and moves perpendicularly with
    EB velocity, and parallel electric field is
    negligible except in resistive boundary layer.
  • Pressure law pressure changes adiabatically via
    EB convection and plasma compression.
  • Gyroviscosity are ignored.
  • ? No particle kinetic physics!

7
Characteristic Scales in NSTX Plasmas
  • Characteristic scales of particle dynamics and
    low-frequency (?, k) perturbations
  • For B 1 T, Te,i 1 keV, eh 100 keV, LB, Lp
    0.5 m,
  • then we have ?i ' 0.3 cm, vi ' 108 cm/s,
  • ?ci ' 108 sec-1, ?bi ' 106 sec-1, ?di ' 105
    sec-1
  • -- temporal scale ordering
  • ?ci ?be ?bh gt ?bi ?i,e
    ?di,e
  • -- spatial scale ordering
  • ?bh gt ?bi gt ?h gt ?i c/?pi gt
    ?e
  • To describe low-frequency (?, k) phenomena, MHD
    model is a good approximation only if (a) ?ci gtgt
    ? gtgt ?t, ?b, ?d and (b) k??i ltlt 1 are satisfied
    for all particle species that have significant
    contributions in density or momentum or pressure.

8
Multi-Scale Coupling Wave-Particle Interaction
  • Multi-spatial scale coupling
  • Finite ion Larmor radius effect (k? ?i O(1))
  • (1) V? i ? V? e ' EB/B2
  • (2) parallel electric field Ek
  • (3) ion gyroviscosity
  • Finite banana orbit width effect (?b k?-1)
  • Small magnetic field scale length (LB ?i)
    particle magnetic moment is not conserved
  • Multi-temporal scale coupling (?t gt ?b gt ?d)
  • - ? - ?d - ?b,t ¼ 0, transit/bounce resonances
    will cause wave energy dissipation or growth
    (fast ion driven TAE instabilities)
  • - ? lt ?b, trapped particles will respond to an
    bounce orbit-averaged field (trapped electron
    stabilization effects on kinetic ballooning
    instabilities)
  • - ? ?d, wave-particle drift resonance effects
    are important for energy dissipation or release
    (fast ion driven fishbones)
  • ? ltlt ?d, particle magnetic drift motion dominates
    over EB drift (sawtooth stabilization by fast
    ions)
  • ? Particle kinetic effects must be included in
    studying NSTX burning plasma physics.

9
Kinetic Effects on Ballooning Modes
  • Consider finite dE due to kinetic effects of
    finite ion gyroradii and trapped electron
    dynamics.
  • A finite dE enhances dJ which provides a
    strong stabilizing field line bending effect.
  • Particle kinetic effects increase (decrease) the
    first (second) critical bC for ballooning
    instability over the MHD prediction.

10
Kinetic Ballooning Mode Equations
Consider finite dE due to kinetic effects of
finite ion gyroradii and trapped electron
dynamics, and the approximate KBM equation is
11
Stabilizing Kinetic Effects on Ballooning Mode
  • For a given electric field perturbation electrons
    move across B differently from ions due to finite
    ion gyroradius effect and charge separation is
    created.
  • Ions move much slower than the wave phase
    velocity along B and is essentially quasi-static.
  • Electrons move much faster than the wave phase
    velocity along B and will play the role of
    keeping charge quasi-neutral.
  • Trapped electrons do not contribute much to
    charge redistribution due to fast bounce motion.
  • Untrapped electrons play the dominant role of
    maintaining charge quasi-neutrality.
  • Untrapped electron density is much smaller than
    trapped electrons and thus an enhanced parallel
    electric field is created to move the untrapped
    electrons to maintain charge quasi-neutrality.
  • Enhanced parallel electric field produces
    enhanced parallel current and thus enhanced field
    line tension, which stabilizes ballooning modes.

12
KBM Stability
Local dispersion relation
At marginal stability ? ' ?pi and critical b is
given by
For low aspect ratio toroidal plasmas
13
Trapped Electron Stabilization of KBMs in Large
Aspect Ratio Tokamaks
14
Small Aspect RatioTorus NSTX
R/a 1.27, a 0.68 m, ? 1.63, ? 0.417, Te
Ti 1 keV, lt?gt 9, qmin 0.93 at r/a 0.3
15
KBM Stability in NSTX (?i?e0)
n12
r/a0.35
16
Stability of KBMs in NSTX
Temperature gradient effect R/a1.27, ?i?e1
Aspect ratio effect R/a1.67, ?i?e0
17
Prediction of TAEs Based on MHD Model
  • TAEs are discrete toroidal Alfven eigenmodes due
    to nonuniform q-profile and nonuniform magnetic
    field intensity along B.
  • High-n TAE equation
  • e r/R , s rq0/q , ?A VA/qR
  • Coupling between neighboring poloidal harmonics
    produces Alfven continuous spectrum gap bounded
    by ?2 ' (1 ?) ?A2/4
  • Magnetic shear allows discrete TAEs with
    frequencies in the gap
  • ?2 ? ?-2 as s ? 0 ?2 ? ?2 as s ? 1
  • TAEs exist because the periodicity in the wave
    potential is broken by magnetic shear similar
    to discrete energy states in a periodic lattice
    due to periodicity breaking by impurity in solid
    state physics.

18
NOVA Alfvén Continuum (n 3) and TAEs in NSTX
(q0 0.7, q1 16)
ltbgt 10
ltbgt 33
  • Large continuum gaps due to low aspect ratio
  • Many TAEs with different ns
  • TAEs can be driven unstable by fast ions if
    nq(Vh/VA) rLh/R?h

19
Kinetic-MHD Model Energetic Particle Physics
  • Two-component plasma core and hot components
    with nh nc , n ' nc, Pc Ph
  • Core plasmas are treated as MHD-fluid
  • Hot particles are governed by kinetic models such
    as gyrokinetic equations or full Vlasov equations
  • Coupling between core plasmas and hot particles
    is via pressure (or current) term in momentum
    equation
  • No parallel electric field

20
Kinetic-MHD Model
  • Momentum Equation
  • r / t Vr V rPc rPh J B
  • Continuity Equation
  • / t Vr r rrV 0
  • Maxwell's Equations
  • B/ t rE, J rB , rB 0
  • Ohm's Law E VB 0, EB 0
  • Adiabatic Pressure Law / t Vr (Pc/r5/3)
    0
  • Hot Particle Pressure Tensor
  • Ph mh/2 s d3v vv fh(x,v)
  • where fh is governed by gyrokinetic or Vlasov
    equation.

21
PPPL Kinetic-MHD Codes
  • Linear Stability Codes
  • -- NOVA-K global TAE stability code with
    perturbative treatment of thermal particle
    and fast ion kinetic physics
  • -- NOVA-2 global kinetic-MHD code with
    non-perturbative treatment of fast ion kinetic
    effects
  • -- HINST high-n kinetic-MHD code with
    non-perturbative treatment of fast ion kinetic
    effects
  • Nonlinear Simulation Codes
  • -- M3D-K global kinetic-MHD code with fast ion
    kinetic physics determined by gyrokinetic
    equation.
  • -- HYM-1 global kinetic-MHD code with fast ion
    kinetic physics determined by full equation of
    motion.
  • -- HYM-2 global hybrid code with ions treated
    by full equation of motion and electrons treated
    as massless fluid.
  • ? Through joint theory-experiment efforts, we
    have gained understanding of energetic particle
    physics phenomena in major tokamak experiments.

22
Fast ions excite large amplitude bursting TAEs,
which cause fast ion loss in NSTX
  • Fast neutron drops correlated with H-alpha
    bursts fast ions hitting wall?
  • Small impact on soft x-ray emission.

(Fredrickson et al.)
23
Bursting TAEs in NSTX NBI Experiments
(Fredrickson et al.)
  • NSTX shot with B 0.434T, R 87 cm, a 63cm,
    PNB 3.2MW.
  • Single dominant mode being n2 or 3, mode
    amplitude modulation represents "beating" of
    multiple modes.
  • Bursting TAEs lead to neutron drop and cause 5
    10 fast ion loss.

24
NOVA-K Study of TAEs in NSTX
NOVA-K Results
NSTX Results
Including plasma rotation
25
Plasma Rotation in NSTX
26
Limitations of Kinetic-MHD Model
  • Negligible fast particle density
  • Ek 0
  • No thermal particle kinetic effects (except in
    the perturbative version of linear NOVA-K code)
  • ? Need a hybrid kinetic-fluid model that treats
    kinetic physics of both thermal and fast
    particles and retains single-fluid frame work.

27
Thermal Particle Kinetic Effects
  • Finite ion Larmor radius (k? ?i O(1))
  • Finite banana orbit width (?b k?-1)
  • Trapped particles
  • Wave-particle resonances
  • ?
  • - finite parallel electric field Ek ¹ 0
  • - wave damping or drive
  • - Kinetic Alfven waves, KTAEs
  • - Radiation damping of TAEs and KTAEs
  • - stochastic ion heating by large amplitude
    Alfven waves
  • - boundary layer physics in kink and tearing
    modes
  • - current layer physics in magnetic reconnection
  • - stabilization of ballooning mode, kink modes

28
Kinetic-Fluid Model
  • High-b multi-ion species plasmas
  • Ordering w lt wci, k?ri O(1)
  • No ordering on nh , nc , Pc , Ph
  • Single-fluid equations consisting of mass density
    and momentum equations, and generalized Ohms law
  • Closure of single-fluid equations by determining
    pressure tensor (including gyroviscosity) from
    particle distributions
  • Particle dynamics governed by kinetic models such
    as gyrokinetic equations or full Vlasov equations
  • Finite parallel electric field

Cheng Johnson, 1999
29
Single-Fluid Equations
  • Mass Density Continuity Equation
  • / t Vr r rrV 0
  • Momentum Equation
  • (/t Vr) V J B r Ã¥j Pjcm
  • Pjcm mj s d3v (v V)(v V) fj
  • Generalized Ohm's law for multi-ion species
  • E VB (1/nee) JB r( Pecm Ã¥i (qi me/e
    mi) Picm)
  • (me/nee2) J/ t r(JV VJ) hJ
  • Ã¥i (mi/rqi 1/nee)(B/B) (r Pi0 B/B)
  • Pi0 mi s d3v vv fi
  • Pressure Tensor diagonal pressures and
    gyroviscosity
  • P P? (I - bb) Pk bb P
  • I is the unit dyadic and b B/B.
  • Pk m s d3v vk2 f, P? (m/2) s d3v v?2
    f

30
Pressure Tensor (one possible model)
  • P? and Pk are determined by f, which is governed
    by low frequency gyrokinetic equations (w lt wci)
  • Gyroviscosity P contains ion FLR and w/wci
    effects and is derived from general frequency
    gyrokinetic equation
  • rP ¼ b (r?dPc b) b r?dPs dPc dPc1
    dPc2
  • dPc1 sd3v (m v?2/2) (J0 2 J10) g0
  • dPc2 s d3v (m v?2 /2) (q/mB) F/m
  • (F vk Ak)(2J0J10 J02) (v?dBk
    /k?)(J0 J1 2 J1 J10)
  • dPs s d3v (i mv?2 /l2)
  • (qF/T)(w0 - wT) /wc (q/mB) (w- kkvk - wd)
    F/m /wc
  • (l J0 J1 J02 - 1)(F vkAk) l(1 2J12)
    2J0J1(v?dBk/2k?)
  • w0 - (Tw/m)ln F/e, l k?v?/wc,
  • F(x, e, m, t) ltfgt averaged over fluctuation
    scales,
  • ? i?/?t and k -ir operate on perturbed
    quantities.
  • Further approximations on FLR can be made!

31
Advantages of Kinetic-Fluid Model
  • Retains framework of kinetic-MHD model
  • Retains naturally global geometrical effects such
    as pressure gradient, magnetic field gradient,
    curvature, etc.
  • Reproduces correct linear eigenmode equations
  • Allows flexibility in modeling particle
    distributions of different species
  • Easier to perform analysis than
    gyrokinetic/Vlasov model

32
Integrated Modeling of Burning Plasmas
a interaction with thermal plasmas is a strongly
nonlinear process.
P?(r,q), Pk(r,q), n(r), q(r)
Global Stability, Confinement, Disruption Control
Fusion Output
a-Heating a-CD
Auxiliary Heating Fueling Current Drive

Heating Power Pa gt Paux
Fast Ion Driven Instabilities Alpha/Fast Ion
Transport
Must develop efficient methods to control
profiles for burn control! ? Need nonlinear
kinetic-fluid simulation codes!
33
Summary
  • Kinetic effects are significant for MHD modes,
    e.g.,
  • -- kinetic stabilization of ballooning modes by
    trapped electron dynamics and ion FLR
  • -- destabilization of TAEs by fast ions
  • Kinetic-MHD codes (linear codes NOVA-K, NOVA-2,
    HINST nonlinear codes M3D-K, HYM) have been
    developed to study fast ion physics.
  • A low frequency (w lt wci) nonlinear kinetic-fluid
    model has been developed to include coupling
    between global modes and kinetic physics of both
    thermal and fast particles.
  • Physics of wave-particle interaction and global
    geometrical effects are properly included in the
    kinetic-fluid model.
  • Extension of kinetic-MHD codes to include thermal
    particle kinetic effects will be developed based
    on kinetic-fluid model.

34
Collaborators
  • PPPL N. Gorelenkov, J. Johnson, E. Belova, G.
    Kramer, E. Fredrickson, G. Fu, R. Nazikian, S.
    Zweben
  • JT-60U Y. Kusama, K. Shinohara, M. Takechi, M.
    Ishikawa, H. Kimura, T. Ozeki, M. Saigusa
  • DIII-D/UCI W. Heidbrink
  • NIFS N. Nakajima
  • IFS J. Van Dam, H. Berk
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