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THEORY SUMMARY

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Error field distorts B topology and kills q=2 TAE = control of hot pressure gradient? ... Discrete TAE in high-beta second-stable tokamak (Hu) ... – PowerPoint PPT presentation

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Title: THEORY SUMMARY


1
THEORY SUMMARY
J. W. Van Dam vandam_at_physics.utexas.edu Please
send me comments!
8th IAEA Technical Committee Meeting on Energetic
Particles in Magnetic Confinement Systems San
Diego, CA 6-8 October 2003
2
OUTLINE
  • Fast ion distribution
  • Fast particle effects on plasma equilibrium
  • Suprathermal electrons
  • Fishbones internal kinks
  • Collective modes
  • TAE
  • CAE, HAE
  • Alfvén cascades
  • Chirping modes
  • Theory
  • Experiment
  • EPM modes
  • Fast ion transport
  • Alpha particles in current-hole plasmas

3
FAST ION DISTRIBUTION
  • Alpha profiles in ITER ELMy H-mode (Budny)
  • Finds 1 NNBI current affects alpha profile
    2 NNBI drive exceeds fast alpha TAE drive 3
    Sawteeth affect the alpha density.
  • Fast particle losses during NSTX reconnection
    events (Yakovenko)
  • Drops in neutron yield during reconnection events
    are due to fast particle losses, not
    redistribution. Probable mechanism magnetic
    drift stochasticity
  • Distribution and fields during ICRH and AE
    excitation (Hellsten)
  • Idea to use ICRH fast ions to simulate alphas
  • JET antenna phasing ( anti- propagation) gt
    different orbits (g emission)
  • Fast ion distribution details are important for
    AE stability/growth
  • ICRH causes decorrelation gt affects nonlinear
    growth of AE modes
  • ICRH fast ion profile and confinement in LHD
    (Murakami)
  • Calculates the velocity space distribution for
    ICRF-heated minority H ions (up to 500 keV of
    energetic tail ions) also the power absorption
    and heat deposition -- good experimental
    comparison
  • Simulates transport of fast ions (especially,
    helically trapped particles)

4
FAST PARTICLE EFFECTS ON EQUILIBRIUM
  • Plasma rotation from ICRF-heated fast particles
    (Eriksson)
  • Several experiments have observed toroidal
    co-current rotation with ICRH plasmas with zero
    momentum injection
  • Possible theories 1 Fast particles, 2
    Neoclassical effects, 3 Accretion process
  • Investigates minority ion heating with co-current
    ICRF waves
  • Fast ions absorb wave momentum, then transfer it
    to plasma (via collisions or radial current)
  • Experiments (JET) and simulations show that fast
    particles may be able to control the rotation
    profile to some extent
  • Formation of internal transport barrier (Wong)
  • Proposes that sheared rotation and negative
    central shear (conducive to ITB formation) can be
    created by having Alfvén eigenmode instabilities
    eject/redistribute alpha particles out of central
    region toward edge gt supported by DIII-D data
  • Estimates that in ITER, number of alphas for this
    mechanism is marginal
  • Ripple reduction with ferritic inserts
    (Shinohara)
  • Experiments (JFT-2M) and simulations (3d OFMC)
    show improved orbit confinement for NBI fast ions
    when ferritic inserts are used (in
    non-shear-reversed plasmas)
  • Speculates about use of large externally created
    local ripple for burn control

5
SUPRATHERMAL ELECTRONS
  • Runaway electrons and disruptions (Helander)
    (Andersson)
  • Two approaches 1 Monte Carlo simulations, 2
    Reduced model
  • Findings
  • Most runaways generated by secondary/avalanche
    mechanism in JET and ITER
  • Typically 50 conversion of thermal current to
    runaways in JET (more in ITER)
  • Runaway density profile 1 Easily corrugated gt
    explain bursty x-ray emission? 2 Peaked on axis
    (more than pre-disruption current) -- observed
    experimentally
  • Particle acceleration at magnetic X-points
    (McClements)
  • Finds both discrete (w/wA 0.8) and singular
    modes
  • X-points can accelerate fast particles

6
FISHBONES INTERNAL KINKS
  • Near-threshold fishbone behavior (Breizman)
  • Fishbone is good example of convective transport
    (single mode)
  • Two-step linear mode structure for
    finite-frequency fishbone
  • Weak fluid nonlinearity of q1 layer destabilizes
    fishbone gt bursting?
  • Fishbone stability with alphas (Fu)
  • Estimates n1 internal kink in ITER is not
    stabilized by alphas (contrary to earlier
    Porcelli theory -- finite orbit width effect?)
  • Fishbone nonlinear saturation (Todo)
  • Mode with n1 saturates, while n0, 2 continue to
    grow
  • Linear gyrokinetic calculation (Lauber)
  • Benchmarked on internal kink
  • Nonperturbative simulation of n1 JET
    observations (Gorelenkov)
  • Reproduces LF ideal and HF resonant modes (but no
    2-step profile -- zero orbit width?)

7
COLLECTIVE MODES TAE
  • JET antenna coil observations (Testa)
  • Complex dependence of TAE damping rate on bN,
    PNBI gt decreases, then increases
  • Damping rate (n1) independent of rI, not linear
    as predicted for radiative damping
  • Error field distorts B topology and kills q2 TAE
    gt control of hot pressure gradient?
  • TAE in NCSX (Fu)
  • Simulation finds unstable TAE mode (n?)
  • 3d geometrical effects reduce its growth rate
  • Discrete TAE in high-beta second-stable tokamak
    (Hu)
  • Existence of mode is due to potential well
    created by high plasma pressure gradient
    (continuum damping is weak)
  • Could be excited by fast particles at bounce
    precession mixed resonance
  • Multi-ion species kinetic/fluid hybrid model
    (Cheng)
  • Will include
  • Gyroviscosity (along with pressure tensor)
  • Hall term in Ohms law (nfast/ne not assumed
    negligible)
  • Thermal particle kinetic effects

8
COLLECTIVE MODES CAE, HAE
  • Sub-cyclotron NBI-driven instabilities in NSTX
    (Belova)
  • Most unstable mode is n4/m2 GAE (nmlt0) with
    w/wci 0.3 large k, large compressional
    component dB/dBperp 1/3
  • Nonlinear saturation level dB/B 10-3 10-4
  • Helical AEs in compact stellarators (Spong)
  • Calculates shear Alfven continuum spectrum for
    W7-AS, QPS, and NCSX find that TAE, HAE, and MAE
    modes are possible
  • W7-AS observes nonlinear bursting with fast ion
    loss and Te drop

9
ALFVEN CASCADE MODES
  • Cascade observations in JET and interpretation
    (Sharapov) (Breizman)
  • Grand cascade (many simultaneous n-modes)
    occurrence is coincident with ITB formation (when
    qmin passes through integer value) gt diagnostic
    to monitor qmin
  • Proposes creating ITB by application of main
    heating shortly before a Grand Cascade is known
    to occur
  • Cascade mysteries (with ICRH fast ions)
  • Transition to TAE as q0 decreases -- calculated
    theoretically
  • No cascade modes at low frequency -- effect of
    continuum damping (calculated)?
  • Sinusoidal frequency rolling -- ?
  • Cascades also occur when toroidicity effect
    exceeds that of fast particles (e.g., low-density
    alphas in TFTR)
  • Reversed-shear Alfven eigenmode observations in
    JT-60U (Shinohara)
  • For NNB injection into reversed shear plasma,
    observe n1 mode located at qmin, with strong up
    and down frequency chirping
  • Earlier such observations were with ICRH fast
    ions
  • Cascade observations in C-Mod (Snipes)
  • Also observe EAE modes in H-mode plasmas (but why
    rotating in we direction?)

10
CHIRPING MODES THEORY
  • Non-adiabatic description of phase-space
    hole/clump (Berk)
  • Predicted frequency bifurcation seen
    experimentally (Gryaznevich/MAST)
  • Frequency sweeping undergoes non-adiabatic
    instability, which can cause sideband generation
  • Simulation of frequency sweeping (Pinches)
  • Two cases
  • JET parameters Only chirps downward (due to
    choice of numerical distribution
    function--experiments see both up/down sweeping
    modes)
  • MAST parameters Up/down sweeping, saturates at
    dB/B 10-4
  • Use as nonlinear diagnostic to infer dB/B from
    chirping rate
  • Nonlinear hole/clump formation (Vann)
  • Simulation of full single-mode (n1) nonlinear
    dynamics gt Finds 4 solutions (damped,
    steady-state, periodic, chaotic) for various
    parameter regimes
  • Simulation of NBI-driven mode in weakly
    reversed-shear NSTX (Fu)
  • Calculates unstable n2 mode (TAE?)
  • Mode structure moves out radially as frequency
    chirps

11
CHIRPING MODES EXPERIMENT
  • Fast ion instabilities in NSTX (Fredrickson)
  • Observation of strongly bursting fast ion loss
    due to multiple TAE modes (2ltnlt6) 40 drop in
    bfast
  • New fishbone-like mode also causes fast ion
    loss (up to 50)
  • n up to 5 (or more) often q(0)gt1 and mgt1
    bounce-precession resonance possibly ballooning
    character strongly chirping when fast ion loss
    is large
  • Coupled to TAEs and CAEs? Correlated with H-mode
    transition?
  • Energetic particle-driven modes in MAST
    (Gryaznevich)
  • Behavior in three distinct regimes
  • Low-beta regime n1 up/down chirping modes
  • Medium-beta regime humpbacked fishbones
  • High-beta regime (Next Step ST) cyclotron-range
    fast particle driven instabilities, but no TAEs
  • No observation of fast ion loss in MAST (smaller
    population?)

12
EPM MODES
  • Bursting modes in JT-60U (Todo)
  • Further measurements (by Shinohara et al.) of TAE
    frequency mode for NNB injection in low-shear
    plasma, now with neutron emissivity diagnostic,
    to study fast ion profile
  • Observe two types of modes fast frequency
    sweeping (FFS) and abrupt large-amplitude events
    (ALE)
  • FFS modes have little effect on neutron
    emissivity
  • ALE modes reduce fast ion population by 20 in
    r/alt0.4 central region gt 14 are redistributed
    to outer region and 6 lost to outside
  • Numerical simulation finds an n1 EPM that is
    nonlocal-- suggested by location (not on
    continuum), frequency (TAE-ish), and profile
    dependence (on fast ion pressure)
  • Frequency chirps both up and down, as in the
    experiment, if fast ion classical distribution in
    the simulation is reduced (due to loss or
    redistribution)

13
FAST ION TRANSPORT
  • Diffusive transport with multiple modes
    (Breizman/Todo)
  • Simulations show intermittent loss of fast ions.
  • Co-injected NBI ions are confined better than
    counter-injected.
  • Phase-space resonances overlap at mode
    saturation.
  • Transition to strong transport in burning plasma
    (Zonca)
  • Onset of fast ion avalanche transport is close to
    EPM linear stability threshold--above which, EPM
    can propagate radially with convective
    amplification. Relay-runner model captures
    nonlinear transport dynamics.
  • EPM-induced alpha particle transport (Vlad)
  • Considers ITER-FEAT, FIRE, and IGNITOR for
    monotonic and reversed shear only ITER is
    unstable wrt EPMs (n2 worst)
  • These unstable modes broaden alpha profile, first
    convectively (via avalanche) and then diffusively

14
ALPHAS IN CURRENT HOLE PLASMA
  • Alpha confinement in current-hole fusion plasma
    (Tobita)
  • Alpha loss can be serious for large current hole
    Loss jumps from 2.0 (at rhole 0.4) to 12.6
    (at when rhole gt 0.5) gt unacceptable for heat
    load on first wall
  • Solution for current hole loss is low aspect
    ratio (1) trapped particles are less sensitive
    to TF ripple (2) TF ripple drops along R
  • VECTOR device (A2, superconducting) Even for
    wide current hole (rhole 0.6), can confine
    alphas (loss as low as 2)
  • Current hole effect on fast ion confinement in
    JET (Yavorski)
  • Orbit of alpha is lost when current hole radius
    equal to or greater than 0.6
  • First orbit loss is enhanced by current hole from
    8-25 for monotonic profile (no hole), to 20-50
    with current hole (of radius 0.6)

15
PERSONAL IMPRESSIONS
  • Signs of health
  • Research
  • New, intriguing experimental findings
  • On-target theoretical explanations
  • Impressive numerical simulations
  • Researchers
  • Significant number of young, talented scientists
    at this meeting
  • Facilities Variety of confinement
    configurations that are currently studying fast
    particle physics (as represented at this meeting)
  • Tokamaks (JET, C-Mod, JT-60, JFT-2M, DIII-D)
  • Spherical tori (NSTX, START, MAST)
  • Helical/Stellarators (LHD, CHS, QPS, NCSX)
  • Others linear (LAPD)
  • Anticipation
  • Short-term
  • New fast particle diagnostics
  • Tritium campaign (JET) planned experiments on
    various machines
  • Long-term
  • ITER

16
POSTSCRIPT
  • Pope of Fast Particle Physics
  • Contributed seminal research (e.g., alpha
    excitation of shear Alfven waves, TAE continuum
    damping, etc., etc.)
  • Trained students in this area
  • Chief Scientist for ITER
  • Participated in previous Fast Particle Tech Comm
    Meetings
  • Yearning for Burning influential advocate for
    ignition physics
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