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Geodesic acoustic modes: simultaneous observation of density, magnetic-field, and flow components in the TCV tokamak. S. Coda, C.A. de Meijere , Z. Huang, L. Vermare 1 , T. Vernay , V. Vuille , S. Brunner, J. Dominski , P. Hennequin 1 , A. Kr ä mer-Flecken 2 , G. Merlo, L. Porte.
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Geodesic acoustic modes:simultaneous observation of density,magnetic-field, and flow componentsin the TCV tokamak S. Coda, C.A. de Meijere, Z. Huang, L. Vermare1, T. Vernay, V. Vuille, S. Brunner, J. Dominski,P. Hennequin 1, A. Krämer-Flecken2, G. Merlo, L. Porte 1LPP, CNRS-EcolePolytechnique, Palaiseau, France 2ForschungszentrumJülich, Germany S. Coda, U.S.-E.U. Joint Transport Task Force Workshop, Santa Rosa, CA, 9-12 April 2013
Outline • Geodesic acoustic modes • Multi-diagnostic measurements of GAMs in TCV • Modeling of GAMs in TCV • Summary and outlook
Zonal flows • Electric potential perturbations: symmetric over flux surface (m=n=0), low-frequency (w0) • Nonlinearly generated by broadband drift-wave turbulence • Associated poloidal, sheared (kr≠0) EB flows break apart turbulent eddies and effectively regulate turbulence self-organization
Geodesic acoustic modes • Finite-frequency (wcs/R) zonal-flow component • n=0, m=1 standing-wave density fluctuation • n=0, m=2 standing-wave magnetic component (recent prediction, Wahlberg 2009) • recent proposal to excite GAM with external magnetic perturbation (Hallatschek 2012)
Geodesic acoustic modes • Flow and density components observed on several devices(Doppler backscattering, reflectometry, beam emission spectroscopy, heavy ion beam probe)
Outline • Geodesic acoustic modes • Multi-diagnostic measurements of GAMs in TCV • Modeling of GAMs in TCV • Summary and outlook
GAMs in TCV • Unique, correlated multi-diagnostic observation • First sighting of magnetic-field component for turbulence-driven GAM • Axisymmetry unambiguously determined • Density: tangential phase contrast imaging • Magnetic field: Mirnov coils • Flow: Doppler backscattering • Radiative temperature: correlation ECE
GAMs in TCV • Initial study: L-mode, limited plasma with 1 MW central ECRH magnetic analysis then extended to broad range of past shots (including Ohmic)
TCV R = 0.88 m, a = 0.25 m Ip < 1 MA, BT < 1.54 T k < 2.8, -0.6 < d < 0.9 ×4 ×2 4.5 MW ECRH power, 7 steerable launchers
Tangential phase contrast imaging (TPCI) • Established technique for measuring line-integrated density fluctuations • Tangential geometry + spatial filtering adds spatial resolution
Tangential phase contrast imaging (TPCI) Ultimate specs:0.9 cm-1 < k < 60 cm-1 (0.2 < krs < 90) spatial resolution down to 1% of minor radius multi-MHz bandwidth
Tangential phase contrast imaging (TPCI) Current specs:1 cm-1 < k < 9 cm-1 line-integratedmeasurement only 1.5 MHz bandwidth
TPCI provides GAM’sspatial distribution and radial wavelength • k is radial TPCI signal comes from tangency point • scan r by moving plasma vertically
TPCI provides GAM’sspatial distribution and radial wavelength
22-40 kHz peaks near edge kr 1.7-2.1 cm-1 (mainly outward)krs 0.4-0.5
Theory: magnetic component of the GAM Bq (r,q,t) q2b sin(2q) sin(krr-wt) • short radial wavelength: faint signal outside plasma • nodes on LFS and HFS, so toroidal mode number should be measured away from equatorial plane
At GAM node location,residual signal dominated by n=1 toroidal mode number n
Magnetic component of GAM has m=2 antinodes and LFS phasing consistent with sin(2q)
Magnetic component of GAM has m=2 HFS phasing indicates presence of m>2 components (effect of shape?)
Doppler backscattering on TCV • Flow measurements performed with a 50-75 GHz tunable, heterodyne system on loan from LPP and Tore Supra • Collaboration with LPP (L. Vermare and P. Hennequin)1 • Monostatic antenna = replica of ECRH launcher, can be oriented in real time 1L. Vermare et al, Nucl. Fusion 52, 063008 (2012)
Oscillating EB GAM poloidal flowis clearly seen in the edge region GAM flow 0.7 km/s rms (background flow 2 km/s)
GAM seen also by correlation ECE Six-channel tunable X2 system, LFS detection
GAM on C-ECE vs TPCI: a few puzzles • plasma is invariably optically thin (t<0.5): ECE measurement is unknown mix of ne and Te fluctuations • kr (TPCI) 1.7-2.1 cm-1, kr (C-ECE) 0.9 cm-1 • predominantly outward-propagating on TPCI, propagation direction depends on location on C-ECE
Global vs local GAM • All diagnostics on TCV see a single-frequency mode irrespective of location • Other devices have reported a single-frequency mode, several discrete modes, or a continuum over r • This variation in behavior is not well understood
Outline • Geodesic acoustic modes • Multi-diagnostic measurements of GAMs in TCV • Modeling of GAMs in TCV • Summary and outlook
Gyrokinetic modeling • ORB5: global particle-in-cell ∂f code • Collisionless, electrostatic simulation using TCV experimental equilibrium and kinetic profiles: turbulence is dominated by trapped electron modes • Model breaks down for r > 0.85, so simulation restricted to inner region (fluctuation level artificially scaled down in edge)
Good, semi-quantitative agreement between experiment and modeling
Good, semi-quantitative agreement between experiment and modeling Multiple discrete modes below a critical density gradient, single mode above (as in experiment)
Good, semi-quantitative agreement between experiment and modeling kr 2.3 cm-1 f 33 kHz coherent over several wavelengths peak amplitude 3 km/s rms peaks at outermost properly simulated radius (r=0.85)
Outline • Geodesic acoustic modes • Multi-diagnostic measurements of GAMs in TCV • Modeling of GAMs in TCV • Summary and outlook
Summary • Initial study on TCV has revealed GAM in density, magnetic-field, and flow fields (plus ECE radiative temperature) • First multi-probe analysis of magnetic component has clearly confirmed axisymmetry • Frequency, radial wave number, poloidal and toroidal mode numbers, radial profile, direction of propagation have all been measured • Good agreement with gyrokinetic modeling
Outlook • Much more to come from the experiment: parametric studies (dependence on q profile, shape, collisionality, etc.), exploration of damping mechanism, etc. • Better diagnostics will be used: fully commissioned TPCI, C-ECE using movable antenna • Much more to come from modeling: synthetic diagnostics for TPCI and C-ECE, parametric studies, etc. • Further challenges to theory: e.g. m>2 magnetic GAM components (finite-b, toroidicity effects)