D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DT experiments On JET D Stork Euratom-UKAEA Fusion Association,

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D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DT experiments On JET D Stork Euratom-UKAEA Fusion Association, Culham Science Centre,Abingdon, Oxfordshire OX14 3DB, UK With acknowledgement to many colleagues in the former JET Joint Undertaking and JET EFDA contributors

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Outline Chronology JET’s unique DT capability The first Deuterium-Tritium Experimental (DTE1) Campaign The Trace Tritium Experimental (TTE) Campaign Building on DTE1 and TTE for future progress

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Chronology Three campaigns with DT operation in JET –Preliminary Tritium Experiment (PTE) – November 1991 One day – Two plasma shots(!!). Tritium injected by NBI. 10% T concentration plasmas > 1.7 MW fusion power for 1 sec. –Deuterium-Tritium Experimental Campaign 1 (DTE1) – May – November 1997 ~ 500 pulses with DT plasmas < n T /(n T +n D )<0.95 –Trace Tritium Experimental Campaign (TTE) Tritium introduced into JET on >150 pulses n T /(n T +n D )≤

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 JET’s unique DT capability JET has a unique capability to study DT tokamak plasmas and processes coupled with a Divertor configuration and an operational Tritium recycling and purification plant. Several ITER-related DT-specific physics topics can be tackled: –‘ELMy H-mode’ validation at high density (n e  n Greenwald ) concept improvement evaluation (impurity seeding, high triangularity, density peaking) –‘Advanced Tokamak’ regime investigation  -particle confinement with high central q isotope effects (threshold, confinement, core-edge interaction) –core  -heating physics and MHD characterisation –DT compatible RF heating scheme qualification ‘Live’ tritium technology testing Validation and demonstration of high gain plasmas (0.5<Q<1)

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 Campaign areas –High fusion gain performance (high Q) ELM-free Hot Ion H-mode (transient Q up to ~ 0.9) Advanced scenario ITB plasmas with Optimised Shear –ELMy H-mode physics Studies of  scaling Transport studies Isotope effects on confinement and L-H threshold –  -heating studies –DT-relevant RF heating physics Overall phenomenology of tritium retention also emerged from this campaign.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results: ELMy H-mode Thermal transport in ELMy H-mode DT plasmas similar to DD plasmas (no strong mass dependence  E ~ A 0 ); Scaling of stored energy is a composite of: –stored energy in the edge pedestal showing stronger isotope scaling (~ A 0.5 ) consistent with pressure limit acting over an ion Larmor radius; –and ‘core’ stored energy with a confinement scaling (  E ~ A –0.2 ) – short-wavelength or Gyro-Bohm turbulence. H-mode threshold lower in DT than in DD ( P L-H ~ A -1 ); ELMy H-mode  scaling of DT plasmas shows Gyro-Bohm (~   ) behaviour.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results: ELMy H-mode If W ped is subtracted from the Total energy – gives the ‘Core energy’ (W core )  core is Gyro-Bohm scaling ( best fit is A -0.17±0.1 ) Analysis shows Ion thermal transport differs in core and edge. Pedestal Energy (W ped ) at r/a >0.85 shows strong A scaling (A 0.5 ) consistent with MHD as the limiting behaviour. Underlying core thermal diffusivities are fitted by ~ A 0.75 – stronger than Gyro-Bohm scaling (A 0.5 )  GB ~ B 0.8 a 3 n 0.6 P -0.6 A -0.2 J G Cordey et al NF39(3) (1999)301

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results : dimensionless scaling to ITER JET D-T ‘wind tunnel’ experiments set up ELMy H- modes with the(then) ITER q,  N and . The data set extrapolated to ITER (ITER-EDA shown) using the standard H-mode scaling. Global confinement is in the D-T plasmas was close to Gyro-Bohm scaling  C  E  *-3 ) J Jacquinot et al, Nuc Fus 39(2)(1999), 235

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results : L-H transition power is lower in D-T plasmas

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results:  -heating Electron heating by  -particles observed in DT plasmas; no TAE or other instabilities seen to be caused by  particles (   ~ max).

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results : electron heating by  - particles At fixed input power, the ratio of T:D (including the T 0 NBI : D 0 NBI) was varied in otherwise similar ELM-free H-mode plasmas (Q~0.65) P R Thomas et al, PRL 25(1998),5548 R   n T n D -- as  T =n T /(n T +n D ) varies, expect to see P  e reach maximum at ~  T ~ 0.5 These experiments limited to max ~ –hence well below threshold of expected TAE modes. Note that the ELM-free phase duration ~ 1-2  s   thus the experiment does not test steady state

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results :  - particle instabilities absent Clear TAE activity seen in RF heated (2  CT ) DT discharges TAE activity from >1 MeV tritons But no TAE activity seen in High performance Hot-Ion DT H-modes Peak  from W DIA

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 ELM-free H-mode DT discharges in DTE1 reached ~ – (~ half foreseen ITER-EDA value), with    ~ DTE1 results :  - particle instabilities absent S Sharapov et al Nucl Fus 39(3) (1999) 373 Q (=P fus /P in )~0.65; P  ~2.4 MW These discharges were close to the lower stable boundaries for core TAE modes – no instabilities seen.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 Results: Dependence of TAE excitation thresholds AE fusion alphas drive terms overcome damping in afterglow after NBI switch-off After the high  phase in DT ITB plasma. TAE modes were seen from ~6.5s TAE modes seen Sharapov, Borba, Fasoli et al NF39 (1999) 373

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results : RF heating 3 schemes tested: –(D)T with low concentration D (<20 %); –( 3 He)DT proposed ITER scheme (at the time); –(2  CT )DT another possible ITER scheme Results for all schemes show good agreement with prediction from the PION code. 3 He minority scheme showed much higher efficiency than (2  CT ). Poor efficiency of the second harmonic scheme partly due to very large orbits from highly accelerated tritons – losses from plasma as orbits intersect the walls.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 This is due to improved Ion heating efficiency Efficiency of 3 He minority is > efficiency for 2  CT due to the latter’s orbit losses DTE1 results : RF heating Adding 3 He minority increases RF heating fusion yield DFH Start et al, NF39(1999),321

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results : Tritium retention in Torus 6 g out of 35 g tritium retained Most retained in carbon flakes at inner Divertor louvres Strong SOL flow drives impurities to inner target Inner divertor plate is colder, thus deposition dominates Flakes may result from C 2 H x release from hydrogen-rich amorphous films Serious consequences for ITER/reactor if not solved - rules out CFC for reactors? P L Andrew, J P Coad at al., J Nucl Mater 1999

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 DTE1 results : transient and ‘steady-state’ fusion power JET: M Keilhacker et al, Nucl Fus 39(2)(1999), 209 J Jacquinot et al, Nucl Fus 39(2)(1999), 235 TFTR: K McGuire et al, Fusion Energy 1996 (Vol 1), 19 (IAEA-CN-64/01-2) Back

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 During TTE the wall tritium fraction kept at <0.5% by frequent pure DD cleanup pulses. Ensured minimisation of background effects - enabled accurate quantification of tritium source Data derived from S/S 2.5:14 MeV neutrons The Trace Tritium Experiment (TTE) took place in September-October Plasmas used Tritium in ‘trace’ quantities n T /(n T +n D )  3% introduced by: short T 2 gas puffs (  6 mg); or T 0 beam injection (~ ms ‘ blips’) At these levels, the plasma 14 MeV and 2.5 MeV neutron yields are ~ equal - gives maximum statistical precision from JET’s neutron detectors. The JET “Trace Tritium” campaign

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 What are the scalings of Fuel Ion transport in steady state? Use of tritium in Particle transport studies: the ambiguity problem in steady-state In principle solve the particle transport equations by fitting density profile and using sources. In eg.source-free case we can in principle integrate within r source Same solution obtained for 2  0, 2  D and 2  v etc. Transient experiments needed to resolve D and v separately

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Accurate timing/ time profile of source (T 2 gas ~ 10ms; thermalised NBI similar) Evolution of tritium profiles derived from 14 MeV Neutron profiles JET neutron profile monitor absolute 2.5 & 14 MeV neutron calibration. 19 channels at r/a< ms time resolution Use of tritium in Particle transport studies All TTE experiments essentially non- perturbative in nature. Tritium introduction into plasmas where all relevant background parameters (T e, n e etc) remained in steady-state. D T and v T can be measured separately. (unlike pure steady- state deuterium plasmas where only D D /v D is evaluated 14 MeV emissivity contours: example immediately after T 2 gas puff T 2 density is hollow: Fast D + from NBI are mainly outboard (trapped and passing) 14 MeV emissivity contours: 800 ms after T 2 puff Profile peaks like 2.5 MeV emissivity once T + density has fully relaxed

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE Campaign Issues Thermal particle transport –comparison of regimes with neoclassical and other models; –MHD effects Fast Particle transport –specific effects of Current Holes –NBI deposition profile effects –Fusion products confinement Diagnostic developments Plasma regimes studied are those of relevance to ITER: --> Internal Transport Barrier scenarios (reversed shear and high central q) --> ‘Hybrid scenarios’ (q 0 ~ 1, sawtooth-free) --> ELMy H-modes (mainly type I ELMs) D T denotes diffusion of thermal Tritium v T denotes advection of thermal Tritium

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: ITB particle transport Reduction of D T to neoclassical in the barrier region Otherwise diffusion>>neoclassical ITB reduces v T, but still stronger than neoclassical I P =2.5 MA; B T =3.2 T

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: ELMy H-mode particle transport Parametric dependence of Fuel-ion particle transport by: –Examining dependence on dimensionless plasma parameters used in transport studies:  *  - Ion Larmor radius normalised to plasma radius; * - Normalised collisionality (~naq/T e 2 )   - Normalised pressure. –Variation of transport vs density. –Variation of transport with additional heating mix (RF+NBI vs NBI only) –Effect on transport of Impurity seeding with Argon (high P RAD fraction ELMy H-modes). In addition, specific MHD effects were charted: – sawteeth; – and Neo-classical Tearing Modes (NTMs) NTMs generally absent from dataset, D T, v T are averaged over ELMs and sawteeth.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 D McDonald et al -- IAEA FEC sub to PPCF ELMy H-mode particle transport: Dimensionless parameter scans Specific data set consists of NBI-heated ELMy H-modes with constant q 95 (~2.8) and  (~0.2): –T 2 gas puffs injected into steady-state phases. –3-point  scan with  and  held ~ constant; –2-point  scan with  held ~ constant; –2-point  scan with  held ~ constant. Outer plasma shows Bohm particle transport Inner plasma shows Gyro-Bohm particle transport

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 ELMy H-mode particle transport: Dimensionless parameter scans (II) Particle transport  and   scans show inverse behaviour of D T : for r/a 0.6 & Thus  P increases with  and  whereas energy confinement is largely independent of  and decreases weakly with  JET & Alcator C-Mod D McDonald et al -- IAEA FEC sub to PPCF

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 ELMy H-mode particle transport: Parameter fits Multi-parameter fit to D T for all ELMy H-mode dataset, shows: -  behaviour between Bohm and Gyro-Bohm; - strong inverse dependence on  ; - weak inverse dependence on  ; -strong dependence on local value of q.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: ELMy H-mode particle transport: Density variation Ratio of Tritium flux through half radius during ‘rise phase’ to predicted Neoclassical flux I Voitsekhovitch et al PoP (sub) Diffusion found to be strongly anomalous at low density. Tritium flux through r/a=0.5 greatly exceeds Neoclassical value at low n e D T dependence on n e is consistent with picture for  Only as n e ~n GREENWALD then D T approaches D NEO,T for r/a<0.6 Greenwald density shot at I P =2.5 MA D T shows inverse density behaviour for all plasma regions K-D Zastrow et al PPCF 46 (2004)B255 Thermal diffusion is less density dependent:->  eff /D T  n e

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: Comparison of different regimes

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Tritium profile evolution was simulated with the Multi-mode model (MMM) - electrostatic turbulence. ELMy H-mode particle transport: Electromagnetic model explains density dependence High Medium Low Tritium density at r/a=0.3 (10 19 m -3 ) High Medium Low Diffusion dependent on density (and hence collisionality) could result from Electromagnetic turbulence (Island size ~ skin depth~ 1/n e 0.5 ) Semi-empirical model with modified neoclassical diffusion in stochastic magnetic field may explain transition to anomalous transport with density FP FP Tritium behaviour is not well- described, (though MMM gives reasonable fits for thermal profiles).  ES turbulence not stabilised with density.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE Campaign Thermal particle transport –comparison of regimes with neoclassical and other models; –MHD effects -- sawteeth -- Neo-classical Tearing Modes Fast Particle transport –specific effects of Current Holes –NBI deposition profiles –Fusion products confinement Diagnostic developments

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Sawtooth mixing of both Fast NBI D + and thermal Tritium is necessary to explain the 14 MeV neutron time history; sawtooth effects most prominent at low density ( peaked D beam deposition); Fast D beam has peaked profile  beam particles removed from core during the sawtooth crash; TRANSP w/o sawteeth with sawteeth sawteeth accelerate T penetration during the rise phase; and its removal during the decay phase; but Rise phase S/T Decay phase S/T Effects of sawteeth were seen in most ELMy H-mode plasmas –D T and v T were nevertheless averaged over the sawteeth. TTE: MHD Effects - Sawteeth oscillations of neutron emission weak or absent during the rise phase, but are enhanced during decay phase. thus

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: MHD Effects Neutron sawteeth simulations TRANSP simulations of 14 MeV neutron time-histories have used: full current reconnection (Kadomtsev) model (q 0 remains ~ 1); partial reconnection (no current mixing) model (q 0 down to ~ larger inversion radius) Full reconnection models the ‘neutron sawteeth’ more accurately. r< r inv r> r inv

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE Campaign Thermal particle transport –comparison of regimes with neoclassical and other models; –MHD effects -- sawteeth -- Neo-classical Tearing Modes Fast Particle transport –specific effects of Current Holes –NBI deposition profiles –Fusion products confinement Diagnostic developments

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: Fast Particle physics In the TTE Campaign, Fast particle physics results were obtained either : - using NBI Tritons directly Beam ion transport in Current Holes; Transport of beam ions at low-q; - using T 0 NBI-derived Fusion products Fusion product confinement/ transport - detecting effects of RF-accelerated protons pT fusion

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July keV Tritons injected into Monotonic Current profiles (MC) and CH plasmas, CH effects demonstrated by 14 MeV neutron profiles from T fast ->D reactions. TTE: Fast Particle physics: NBI transport in Current Holes Current Hole (CH) plasmas have near-zero Toroidal current density in plasma centre r/a < typically an ITB at the CH edge. Good thermal energy confinement inside the ITB, but CH expected to confine Fast Ions poorly due to low-central B   Vert. Horiz On-axis -->Outward profile shift seen in CH plasmas compared to MC plasmas N C Hawkes et al, PPCF Dec 2004

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: Fast Particle physics: NBI transport in Current Holes Fitting Neutron camera channel signals gives centroid of NBI triton peaks. Sudden erosion of CH, eg. By MHD activity, is seen as NBI triton centroid makes sudden jump. For series of CH discharges, NBI triton centroids correlate with edges of CH measured by fit to MSE B Z profile.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: Fast Particle physics: NBI transport in Current Holes Outward shift of NBI triton peak is due to shift of ‘stagnation orbits’ of the tritons in the very low central B Z field. 14 MeV neutron profiles Data/simulations -- on-axis NBI tritons Neutrons m -2.s -1 (10 15 ) This can be qualitatively modelled by either 3-D Fokker Planck code or by TRANSP Monte Carlo 3-D F-P code TRANSP N C Hawkes et al, PPCF 2004

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE : NBI fast ion studies Tritium beams Reminder of experimental set- up: –on-axis and off-axis T beams were used –2-D neutron camera Neutron camera

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: NBI fast ion studies Results for monotonic q-profile: –Neutron profiles agree with calculation at high q 95 (~8.5) –Modelling reproduces on-axis beam case at low q 95 (~3.3) … but not off-axis beam case Conclusions: –Suggests fast ion redistribution –No clear MHD cause –Further work needed to clarify cause and implications I Jenkins et al, 32 nd EPS Tarragona

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE Campaign Thermal particle transport –comparison of regimes with neoclassical and other models; –MHD effects -- sawteeth -- Neo-classical Tearing Modes Fast Particle transport –specific effects of Current Holes –NBI deposition profiles –Fusion products confinement Diagnostic developments

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Diagnostic developments in TTE TTE Campaign saw significant Diagnostic activity with relevance to diagnosis of Burning Plasma Experiments. Already covered: –14 MeV neutron camera -- much useful asymmetric profile data -- shows that ITER will need radial and vertical cameras; In addition: –Gamma-ray diagnosis of alphas -- profiles also obtained with the camera detecting gammas from RF accelerated 4 He alpha simulation -- need to install 6 LiH collimators on the JET Neutron camera to shield out the 14 MeV background for Fusion Product profile work –first calibration/use of Carbon Vapour Deposit (CVD) diamond detector with Tokamak plasmas; –Magnetic Proton Recoil (MPR) spectrometer gave 14 MeV neutron spectrum from RF heated tritium minority (  cT and 2  cT ) -->triton ‘tail temperature’; –Compact organic NE213 and Stilbene (C 14 H 12 ) detectors tested.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July MeV  -ray emission measures changes in the LOS density of the fast  - particles with E  > 1.7 MeV post-NBI. BGO Line of sight TTE: Diagnostics:  –ray detection of Fusion products transport/confinement  -ray spectrometry has provided information on the behaviour of fusion  - particles in TTE  -particle diagnosis was based on nuclear reaction 9 Be( ,n  ) 12 C following  -production in T (F) + D > n +   -ray intensity after the T-blip is seen as ~ I  (t)  exp(-t/   ) 14-MeV neutron rate corrects background

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 TTE: Diagnostics:  –ray detection of Fusion products transport/confinement (II)   - measured 4.44-MeV  -ray decay rate  T +   - calculated classical combined slowing down parameter tritons from 105 keV to 40 keV plus  ’s from 3.5+ MeV to 1.7 MeV For a wide range of discharges compare two quantities   exp    +  T   exp <   +  T V G Kiptily et al., PRL 93 (2004) This group also has reduced initial signal (First orbit losses)

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Good  -confinement: Critical plasma current I CR > 1.5-2MA to avoid significant orbit losses/drift   exp    +  T Discharges with monotonic q-profiles: B T = T, I p = MA Poor  -confinement: drift & orbit loss   exp <   +  T Low plasma current : 1MA‘Current Hole’ Discharges Current hole effect equates to an increase of the critical plasma current: I CR  1/(1-x H 1/2 ), x H =r H / a: for  ’s when x H = 0.35 I CR  3.7 MA TTE: Diagnostics:  –ray detection of Fusion products transport/confinement (III) Technique still in infancy, but shows promise – see Yavorskij et al 32 nd EPS Tarragona

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Building on DTE1 and subsequent progress a new agenda for ‘50:50’ DT plasmas DTE1 was a great success, but several issues addressable in a ‘sub-burning plasma’ were not satisfactorily resolved and since then new advances have opened up, or may open up, new experimental opportunities. –ELMy H-mode -- JET now works routinely near n e ~ n GW -- T e ~T i regimes -- scaling to ITER? –Optimised/ Reversed shear/ Advanced Tokamak -- never satisfactorily demonstrated in DT (scenario problems, fuel control) -- develop to steady state -- higher P add available; –  - particle physics -- higher P  would be available in SS OS/AT plasma; –RF DT scenarios, systematic work with polychrome heating to overcome high tail temperatures in 2  CT -- more exploration of ( 3 He)DT -- mixture control and ‘ash’ build-up?.

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005  pressure levels in various JET discharges Much lower threshold seen for ICRF-driven AEs in RS and OS discharges cf. ELMy H-modes (result of higher central q – energetic ion coupling to AE increases in efficiency as  ~ q 2 ). Alpha levels in past JET discharges at high performance are similar to ‘ITER/reactor’ levels. relatively high R  f in OS/RS plasmas --good candidates for fusion-driven AEs Simple scaling of JET Performance when higher power available (2009) shows (Pamela, Stork et al., NF42(8) (2002) 1014): - for 38 MW I/p (27 NBI/11 RF) at 3.5MA/3.4T and if  N =3 accessible MW fusion power and <    should test stability limits

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Building on TTE and subsequent progress a new agenda for trace - T plasmas The efficacy of controlled Trace-tritium studies for thermal and fast particle transport is demonstrated. ELMy H-mode studies reveal interesting dependences different from energy confinement, but: –in neo-classical terms, some of the discharges (low I p ) are in the plateau-regime -- do these scalings hold when dataset dominated by banana-regime? (include 4 MA plasmas) ITB plasmas studies show neo-classical behaviour of the barrier and potential fuelling efficiency problems inside barrier, but: – particle transport scaling in ITB plasmas remains to be identified (scaling studies needed and direct comparison with He ash transport required). Hybrid scenario-- only a few basic results -- must build on these. Fast particle studies –  -ray detector shows great promise - now need to convert the multiple channels of the KN3 camera -- 6 LiH collimators needed. –NBI current drive profiles - more investigation of systematics at low-q

D Stork—IEA Workshop W60 “Burning Plasma Physics and Simulation – Tarragona, 4-5 July 2005 Finally…. We still know very little about Tritium Retention in Tokamak surfaces … even Carbon! –Some evidence from TTE that plasma clean-up methods had improved since DTE1 - no time to pursue this. It is absolutely essential that JET returns to Tritium operation before the wall material is changed and that particular attention is paid to retention within the divertor surfaces. Comparison can then be with the Beryllium/Tungsten wall mix installed when the new JET wall goes in.