Title: Recent Results from the H1 National Facility
1Recent Results from the H-1 National Facility
Boyd Blackwell , M. Hole, J. Howard, D.G. Pretty,
J.H. Harris, S.M. Collis, D. Andruczyk, B.W.
James, F.J. Glass, T.A. Santhosh Kumar, M.G.
Shats, C.A. Michael, H. Punzmann, G.G. Borg H-1
National FacilityAustralian National University
2H-1NF National Plasma Fusion Research Facility
- Established in 1997 by the Commonwealth of
Australia and the Australian National University - 12/2005 Contract signed to extend operation to
2010 and fund operational costs from the existing
grant. - The Board is being re-constituted to encourage
development of collaborative proposals covering a
broader range of areas (e.g. advanced energy,
fusion science and technology and materials). - Mission
- Detailed understanding of the behaviour of
magnetically confined hot plasma in the HELIAC
configuration - Development of advanced plasma measurement
systems - Fundamental studies including turbulence and
transport in plasma - Contribute to global research effort, maintain
Australian presence in the field of plasma fusion
power - The facility is available to Australian
researchers through the AINSE1 and
internationally through collaboration with Plasma
Research Laboratory, ANU. - 1) Australian Institute of Nuclear Science and
Engineering
3H-1 Heliac Parameters
- 3 period heliac 1992
- Major radius 1m
- Minor radius 0.1-0.2m
- Vacuum chamber 33m2 excellent access
- Aspect ratio 5 toroidal
- Magnetic Field ?1 Tesla (0.2 DC)
- Heating Power 0.2MW 28 GHz ECH 0.3MW 6-25MHz
ICH - Parameters achieved to dateexpected
- n 3e18 1e19
- T 100eV(Te)500eV(Te)
- ? 0.1 0.5
4E-Beam mapping (wire tomography)
B.D.Blackwell, J. Harris, T.A. Santhosh Kumar,
J.Howard
- Rotating wire array
- 64 Mo wires (200um)
- 90 - 1440 angles
- High accuracy (0.5mm)
- Moderate image quality
- Always available
- Tomography Challenges
- Asymmetric resolution
- Undersampled in impact radius
- only 64 wires, unlimited data in ?
- Somewhat perturbative
- Collected current on one wire steals from
another
5E-Beam Tomography Raw Data
M2 island pair
For a toroidal helix, the sinogram looks very
much like part of a vertical projection (top view)
Sinogram of full surface
6E-Beam mapping
- Good match between computed and measured
surfaces - Sensitive to shear ? identify sequence
number ? high shear surfaces smear
7H-1 Remote control/Automatic scans
Cooling, vacuum and sequence control Generator
and heating power control
8Poloidal mode number measurements
phase
Expected for m 2
magnitude
- bean-shaped 20 coil Mirnov array
- Phase vs poloidal angle is not simple
- Boozer coords
- External to plasma
- Propagation effects
- Large amplitude variation
- Phase problem reduced at higher m, amplitude
problem worsens. - Significant interpretation problem in advanced
confinement configurations
Coil number
Coil number
9Identification with Alfvén Eigenmodes
phase
- Coherent mode near iota 1.4, 26-30kHz, Alfvénic
scaling with ne - m number resolved by bean array of Mirnov coils
to be 2 or 3. - Cylindrical theory predicts two possible GAEs at
m2, and m3 - Resolve by analysing data from second bean to get
both an independent value of m, and an estimate
of N (in progress). - Many other examples of Alfvénic scaling
Two possible GAEs 20-25kHz
10Planned Exploration of EPM Physics
(also with M. J. Hole, L. C. Appel)
- Passive Alfvén eigenmodes Synergistic
theory/experiment study of wave drive, and effect
on confinement. - Experiment Multiple sources of non-thermal
particle populations RF heating, ECH, molecular
beam and gas puff.
- Diagnosis. Essential for EPM studies. Some
include - ne tomographic interferometer. (10kHz, 2cm
resol.) - Ti,vi coherence imaging optical system
- ?Bext 2 x 20 coil Mirnov arrays ? (m,n) up
to 200 kHz - ?Bext CAE measurements, flt 5MHz OMAHA coils
(UKAEA) - ?Bint sensitive mm-wave homodyne
polarimeter/interferometer.
200 kW, 28GHz gyrotron
- Active Excitation
- Compressional Alfvén antenna 100s kW.
- Selective frequency tuning for electron or ions
(4-26 MHz)
11Multiple Fluid Modelling
(M. J. Hole, G. Dennis)
- Multiple different energetic populations present
- H-1 thermal ions, electrons, injected cold fuel
ions, energetic ions/electrons driven by
wave-particle resonance heating, and runaway
electrons, - MAST energetic ions produced (indirectly) via
injected neutral beams, - ITER fusion-born ?s
- Distribution functions will be modelled by a
combination of functional parameterisation and/or
numerical simulation.
- Moments of the distribution functions ? Multiple
fluid model
- Preliminary Working Extension of PPPL/ Univ. of
Rochester code FLOW to handle multiple Maxwellian
populations.
12Data Mining handles large quantities of data
D. Pretty
- 4 Gigasamples of data
- 128 times
- 128 frequencies
- 2C20 coil combinations
- 100 shots
- Data mining allows sub sampling, exploring and
rule extraction - Initial work with Weka java and Gabor
transforms for time freq analysis - Huge data sets are a common problem in complex
geometries often associated with advanced
confinement configurations
D. Pretty
13Mode Decomposition by SVD and Clustering
D. Pretty
- 4 Gigasamples of data
- 128 times
- 128 frequencies
- 2C20 coil combinations
- 100 shots
- Initial decomposition by SVD ? 10-20 eigenvalues
- Remove low coherence and low amplitude
- Then group eigenvalues by spectral similarity
into fluctuation structures - Reconstruct structuresto obtain phase difference
at spectral maximum - Cluster structures according to phase differences
(m numbers) - ? reduces to 7-9 clusters for an iota scan
14Mode Decomposition by SVD and Clustering
D. Pretty
- 4 Gigasamples of data
- 128 times
- 128 frequencies
- 2C20 coil combinations
- 100 shots
- .
- Cluster structures according to phase differences
(m numbers) - ? reduces to 7-9 clusters for an iota scan
- Grouping by clustering potentially more powerful
than by mode number - Recognises mixtures of mode numbers caused by
toroidal effects etc - Does not depend critically on knowledge of the
correct magnetic theta coordinate
m0,3,5
m3,1
m3
m2
m0
m1
m1,2,3
m4
15Alfvén resonant frequencies overlaid on Clusters
E and F
D. Pretty
16Helium Diagnostic Beam
The University of Sydney
- Purpose to locally measure Te and ne (Sasaki et
al.) - Very narrow (15mm) very brief (200us) burst of He
- 1019 atoms /m3
- tiny increase in base pressure
- Allows point localised measurements
Skimmer Pulsed jet
D. Andruczyk, S. Collis
17Helium Diagnostic Beam - results
- Very narrow (15mm) very brief (200us) burst of He
- 1019 atoms /m3
- tiny increase in base pressure
- Allows point localised measurements
- Fires every 2 msec
- ? time evolving radial profiles (Sasaki et al.)
- Example shows ECH collapse in dirty plasma
- For plasma gt 100eV, results not so clear at
present
Background increase due to impurity Si
18Recent Results (2005)
- Configurational effects demonstrated
- particle confinement effects, magnetic fluct.
spectra - Poloidal mode numbers identification with Mirnov
array, Toroidal soon - Alfvénic modes observed
- Datamining unsupervised reduction of 40 probes
in 100 configurations into physically significant
clusters - New campaign of surface and magnetic island
mapping to provide insight into configuration
scan - Fast scanning density interferometer profile in
lt 2 ms (Alfven, islands) - Tomographic emission and temperature imaging
demonstrated - Possible without assumption of magnetic surfaces,
kHz time resolution - Ion temperature via 4 frame phase-split
interferometric imaging - Two supersonic directional gas jets for fuelling
and imaging diagnostics operational - Multi Point measurements of Te via He line ratio,
multi-pulse - Engineering improvements
- Extensive remote control of operation ? computer
scans, automatic logging - ECH magnet current controlled by PLC to /-
0.5Amp, Bolometer in W/G
19Future
- Dynamics - modulation of n and T, gas puffing
- possibility of high field confinement transitions
with increased power - New diagnostics
- Second Soft Xray array with interchangeable foil
(University of Canberra) - Triple probe array (T3)
- LIF E-field measurements
- Heating RF and ECH higher power, higher
temperature - 200kW ECH, 250kW RF, improved discharge cleaning
- Progression to high temperature e.g.
- Turbulence/Flow studies via correlation
spectroscopy, microwave scattering - Radial force balance information via MOSS
spectroscopy - Extensive Configuration Studies
- three control windings ? iota, well and shear
- higher power for stability studies approaching ?
0.5 - interchange, ballooning modes.