Radial-Basis Function Networks Radial-Basis Function Networks
Progress in Physics Basis and its Impact on ITERProgress in Physics Basis and its Impact on ITER M....
Transcript of Progress in Physics Basis and its Impact on ITERProgress in Physics Basis and its Impact on ITER M....
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Progress in Physics Basisand its Impact on ITER
M. Shimada1, D. Campbell2, R. Stambaugh3, A. Polevoi1, V. Mukhovatov1,N. Asakura4, A.E. Costley1, A.J.H. Donné5, E.J. Doyle6, G. Federici7,
C. Gormezano8, Y. Gribov1, O. Gruber9, W. Houlberg10, S. Ide3, Y. Kamada3,A.S. Kukushkin7, A. Leonard3, B. Lipschultz11, S. Medvedev12, T. Oikawa1,
M. Sugihara1
1ITER IT, Naka Joint Work Site, Naka-machi, Naka-gun, Ibaraki-ken, Japan 311-0193, 2EFDA,3General Atomics, 4JAERI, 5FOM-Rijnhuizen, 6PSTI UCLA, 7ITER IT, Garching Joint Work Site,8ENEA Frascati, 9IPP-Garching, 10ORNL, 11PSFC MIT, 12Keldysh Institute
Acknowledgement to Dr. Y. Shimomura of IT, Prof. H. Bolt, Dr. A. Loarte and Dr. G. Pautasso ofIPP Garching, Dr. V. Philipps of IPP Jülich, Prof. A. Fukuyama of Kyoto University, Dr. F. Zoncaof ENEA Frascati, ITPA Topical Groups, Coordinating Committee and ITER IT
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Outline Physics R&D through ITPA Areas where progress is good Theory-based transport modeling Edge Localised Modes (ELM) Neoclassical Tearing Modes (NTM) Weak Magnetic Shear Operation Resistive Wall Modes (RWM)
Areas where much more work is needed Plasma-Wall Interaction (PWI) Disruptions Instabilities driven by Energetic
Particles Summary
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Physics R&D through the International Tokamak Physics Activity(ITPA)
Coordinated physics R&D for ITER is undertaken to develop andimprove methodologies for projection and control of ITER through theITPA.
All ITER Parties (RF, EU, JA, US, CN, KO) are participating. Significant progress has been made since the publication of the ITER
Physics Basis. This has improved the confidence of ITER achievingits goals.
A review paper of tokamak physics for burning plasmas is inpreparation to be published in Nuclear Fusion.
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Theory-based transport modeling in the core + empirical pedestalmodel predicts Q ~ 10 in ITER inductive operation (Bateman)
Zeff ~ 1.3 is assumed
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Edge Localised Modes (ELM)The amplitude of ELMs can be reduced by inducing frequent ELMs bypellet injection (ASDEX Upgrade) or by edge ergodisation (DIII-D)
ASDEX Upgrade
With pelletinjection, asmall confinementdeterioration(~10%) isobserved.
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Neoclassical Tearing Modes (NTM) Suppression by ECCDSuppression of NTM hasbeen demonstrated for 2/1and 3/2 modes (ASDEXUpgrade, DIII-D, JT-60U).The magnetic island istracked real-time and earlyinjection has reduced therequired power (JT-60U).
The required power in ITER is estimated to be 10-30 MW
Good confinement is observed in the presence of n=2 or 3 tearingmodes
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Weak Magnetic Shear Operation (1)Weak magnetic shear (high βp, “hybrid”, q(0) = 1-1.5) discharges showimproved confinement and high β. (e.g. H98(y,2) ~ 1.2 at n/nG = 0.85) InITER, fusion powers of ~ 350 MW, Q~ 20 and tburn > 1000 s would beexpected at βN ≤ 2.2 (< βno wall). This would make an attractive scenariowith high Q, long pulse and small ELMs.
ITER
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Weak Magnetic Shear Operation (2)
0
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0.4
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0 0.2 0.4 0.6 0.8 1
j, MA/m2
X
q
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jec
jnb
jtot
jbs
q
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8
A weak shear steady statescenario of ITER with thecurrent drive systems of theinitial operation, i.e. 33 MWNB and 20 MW EC
SSNβ =2.76, βN
no wall =3.0, li=0.87, HH98(y,2) = 1.7,
95min0 // qqq =1.72/1.54/5.74
Advantage: free of Resistive Wall Mode (Polevoi, IT/P3-28)
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Resistive Wall Modes (RWM)DIII-D experiments demonstrate that RWM can be suppressed by acombination of plasma rotation and feedback control with externalcoils. An analysis shows that RWM control is possible up to Cβ ~ 0.8(Cβ = (β − βno wall)/(βideal wall − βno wall)) in ITER. (Liu and Bondeson, TH/2-1,Gribov and Kavin, IT/P3-22)
ITER
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Disruptions (Electromagnetic load)
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ASDEX-UC-MODDIII-D (90=>10)Ip0
JET (100 => 40)Ip0JT-60U
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S (m
s / m
2 )
Ip0
(MA)
Δt=Ip0/<dIp/dt>80=>20 except for DIII-D and JET
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by Eddy current
by Halo current
Design target
ITER
Forc
e on
key
(MN)
Time after TQ (ms)
Force on key of # 1 moduleDownward VDE with fast quench
EM load has been analysed on the basis of current quench time andhalo current (TPF x Ihalo/Ip0 ≤ 0.7) derived from experiments. Withconservative assumptions, there is a moderate margin. Mitigationsystem is under development (Sugihara, IT/P3-29)
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Disruptions (energy load) (Loarte, IT/P3-34)
The thermal quench causes a heavy energy load on the divertortargets (30-100 % of stored energy in AUG, < 50 % in JET, 50-100 % inDIII-D), indicating that high-Z material would melt if used for ITERdivertor targets. Rough surfaces would melt during normal operation
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Plasma-Facing Components (initial phase)
Graphite CFC Divertor Target:No Melting under transient Power LoadsCompatibility with wide Range ofPlasma RegimesBecause of T retention, the use of CFCshould be minimized.
4 changeovers of divertor targets
W Baffle/Dome: low Erosion, long Lifetime
Be first wall & limiter: low Z + O2 getterA changeover of FW is possible in ~ 1 yr(4 In-vessel vehicles, possibly partial replacement)
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Tritium Inventory ControlA large uncertainty exists in the T build-uprate. Recent JET results show fuel retentionrates of ~ 3 % or lower. This means >88,000s available for 400 MW burn before reaching350 gT in ITER. (Safety analysis: 1000 gT)
Be coverage of CFC greatly reduces Tbuild-up (PISCES).
Development of methods to remove tritiumesp. from the shadow is a high priority (e.g.Ion Cyclotron wall conditioning couldremove 350 gT in ~10 days(Tore-SUPRA),but not from the shadow).
These suggest T retention is manageableduring very low duty cycle experimentalphase.
It is desirable to remove C targets before high duty operation.Schemes for disruption control and impurity control should be established by then.
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Instabilities driven by Energetic Particles
NOVAK analysis of AlfvénEigenmode shows that n =10-12 are unstable andinjection of 1 MeV neutralbeam would make n = 7-17unstable in the ITERnominal inductive scenario[Gorelenkov].
In configurations with reversed shear, drift-kinetic Alfven Eigenmodesand Energetic Particles Modes could be made unstable [Briguglio,Jaun], which could set an upper limit to the minimum q-value in ITER.
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Summary
Validation of core transport models has progressed and analysis withITER parameters confirms that the achievement of Q > 10 in theinductive operation is feasible.
Improved confinement and beta have been observed with low shear(=high βp=”hybrid”) operation scenarios in many tokamaks. If similarnormalized parameters were achieved in ITER, it would provide anattractive scenario with high Q (>10), long pulse (>1000 s) operationwith beta < no wall limit and benign ELMs.
For improved physics understanding, more work remains in theareas of transport of momentum and particle and transport andstability in the pedestal and TAE modes. For reliable and high dutyoperation, further work is important to develop the control schemesof ELM, impurity, NTM, RWM, disruption and tritium retention.