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Pedestal Confinement and Stability in JET-ILW ELMy H-modes
EX/3-3: Pedestal Confinement and Stability in JET-ILW ELMy H-modes CF Maggi Max Planck Institut für Plasmaphysik, Garching, Germany 25th IAEA FEC Conference, St Petersburg, Russian Federation, 2014
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JET-EFDA, Culham Science Centre, Abingdon, OX14 3DB, UK
Acknowledgements S. Saarelma1, M. Beurskens1, C. Challis1, I. Chapman1, E. de la Luna2, J. Flanagan1, L. Frassinetti3, C. Giroud1, J. Hobirk4, E. Joffrin5, M. Leyland6, P. Lomas1, C. Lowry7, G. Maddison1, J. Mailloux1, I. Nunes8, F. Rimini1, J. Simpson1, A.C.C. Sips7, H. Urano9 and JET Contributors* JET-EFDA, Culham Science Centre, Abingdon, OX14 3DB, UK 1CCFE, Culham Science Centre, Abingdon OX14 3DB, UK 2Asociacion CIEMAT, Madrid, Spain 3Association VR, Fusion Plasma Physics, KTH, SE Stockholm, Sweden 4Max Planck Institut für Plasmaphysik, Boltzmannstr. 2, Garching, Germany 5CEA, IRFM, F Saint-Paul-lez-Durance, France 6York Plasma Institute, Department of Physics, University of York, York YO10 5DD, UK 7European Commission, B1049 Brussels, Belgium 8Associação IST, Instituto Superior Técnico, Av Rovisco Pais, Lisbon, Portugal 9Japan Atomic Energy Agency, Muko-yama, Naka, Ibaraki , Japan *See the Appendix of F. Romanelli et al., Proc. 25th IAEA FEC 2014, St Petersburg, Russian Federation
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Confinement reduction in pedestal
In JET-ILW, H-mode operation needs to be compatible with W control Lower Te,PED in initial phase of JET-ILW at all densities Confinement loss is dominantly in pedestal N2 seeding in high d H-modes allows recovery of Te,PED to values approaching JET-C JET-C Low d High d 2012 JET-ILW High & Low d High d + N2 seeding [Beurskens, PPCF 2013] [Giroud, Nucl. Fusion 2013] ( MA / T, PNBI = MW), bN ~ 1.2 Similar pPED at low and high d in JET-ILW at low bN (~ 1.2)
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Outline Experiments in with the JET-ILW have investigated the pedestal confinement and stability with respect to: Triangularity Beta Neutrals (D and low-Z impurities)
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Triangularity alone does not recover pedestal height
j high-d low-d Operational point at low Te,PED 2014 Lower Te,PED Higher n*PED lower bootstrap current plasma shaping barely affects the achievable pedestal height Similar pPED at low and high d de la Luna, EX/P5-29 Triangularity alone does not recover pedestal height
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Pedestal pressure and beta
high-d low-d high-d, high bp p’ j Low D2 gas injection Increasing power/beta increases pPED both at low and high d At low beta similar pedestal pressures At high d, stronger increase in pPED with power at constant density Challis, EX/9-3
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Pedestal stability consistent with P-B
Increasing core pressure stabilises ballooning modes due to Shafranov shift, which raises P-B boundary Pedestals limited by intermediate-n P-B instabilities before type I ELM crash, both at low and high d Low D2 gas injection Challis, EX/9-3
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Power scans at higher gas rates
Higher D2 gas rate, typical of JET-ILW steady H-modes 1.4MA /1.7T, Low triangularity Lower bN at higher D2 gas rate Type I ELMs Lower pPED at larger gas rate (Psep = Pheat – Prad,bulk)
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Peeling-Ballooning stability
At low gas rates, pedestals are at P-B boundary At high gas rates, pedestals are stable to P-B modes at higher beta All type I ELMy H-modes Weaker increase of pedestal pressure with power at high D2 gas rates is not consistent with peeling-ballooning model
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Varying the plasma neutral content
Neutral D content increases when D2 injection rate is increased W control tool Divertor configuration is varied from C/C or V/H C/V (pumping efficiency + neutrals recirculation to main chamber) V/H C/C C/V Low d Major Radius [m] Height [m] -1.2 -1.4 -1.6 -1.8 Cryopump [Tamain, PSI 2014], [Frassinetti, EPS 2014] Joffrin, EX/P5-40
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Pedestal pressure and neutrals
C/C: good pumping + lower neutral content ne,PED , Te&i,PED C/V: good pumping + higher neutral content ne,PED , low Te&i,PED V/H C/C C/V Low d Major Radius [m] Height [m] -1.2 -1.4 -1.6 -1.8 Cryopump de la Luna, EX/P5-29 Joffrin, EX/P5-40
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In C/C, H98 ~ 1 and bN ~ 1.8 at 2.5MA V/H C/C
Increase of Wth at similar pPED but lower collisionality ne ne normalized Te Te normalized pe pe normalized [Frassinetti, EPS 2014]
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In C/C, H98 ~ 1 and bN ~ 1.8 at 2.5MA V/H C/C
Increase of Wth at similar pPED but lower collisionality ne ne normalized Te Te normalized V/H C/V Low pedestal and core pressure pe pe normalized [Frassinetti, EPS 2014]
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At high d N2 seeding increases Te,PED
2.5MA/2.7T d = 0.4 Increase of Te,ped is independent of divertor configuration Effect on density depends on divertor configuration Increase of Te,PED with N2 is weaker at low d The underlying physics process is not yet understood Giroud, EX/P5-25
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Pedestal structure with D2 and N2
2.5MA/2.7T, High Triangularity, V/H Configuration At high gas rates, challenge for KBM based EPED model D2 N2 With increasing D2 rate, pressure gradient decreases and width increases at constant bpol With increasing N2, temperature pedestal widens and peak density gradient increases [Leyland, Nucl. Fusion, accepted]
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Conclusions The changeover from JET-C to JET-ILW has forced us to re-optimize pedestal confinement and stability What we understand within the P-B framework and EPED model: Stabilizing effects of beta and plasma shaping at low D2 gas rates What we still need to understand in order to advance our predictive capability of the pedestal height: Physics process through which D neutrals degrade Te,PED (inter-ELM transport?...) Physics process through which N2 impurities increase Te,PED
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Back-up slides
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P-B stability analysis
#87341 Distance of operational point to P-B boundary is length of arrow, calculated at fixed pedestal width and increasing Te,PED
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Gyrokinetic analysis of the pedestal
Local flux tube simulation (GS2) indicates that JET pedestal is stable to KBMs due to high bootstrap current JET-C, #79498, 2.5MA /2.7T [Saarelma, Nucl. Fusion 2013]
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Pedestal prediction EPED predicts fully developed pedestal before an ELM at crossing of KBM and P-B stability limits EPED has predicted the pedestal height in several devices within ± 20% [Snyder et al., NF 2009] [Snyder et al., NF 2011]
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Stability boundary in P-B analysis
High-n ballooning: Inclusion of higher toroidal mode numbers reduces the critical pressure gradient at which ballooning modes become unstable, changing the stability boundary Diamagnetic stabilization: BOUT++ simulations indicate that g > w*max/2 at low n and g > C * wA at high n is more appropriate
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