Heat Load Measurements on the JET First Wall During Disruptions

1. Heat Load Measurements on the JET First Wall During Disruptions G.Arnoux1, B.Bazylev2, S.Devaux3, T.Eich3, W.Fundamenski1, T.Hender1, S.Jachmich4, A.Huber5, M.Lehnen5, A.Loarte6, U.Kruezi4, V.Riccardo1, G.Sergienko4, H.Thomsen7 and JET-EFDA Contributors 1 EURATOM/CCFE Association, Culham Science Centre, Abingdon, Oxon, OX14 3DB 2Forschungzentrum karlsruhe GmbH, PO Box 3640, D-76021 Karlsruhe, Germany 3Max-Planck-Institut für Plasmaphysik, EURATOM-Assoziation, D-85748 Garching, Germany 4Institüt für Energieforschung – Plasmaphysik, Forschungzentrum Jülich, trilateral Euregio Cluster, EURATOM-Assoziation, D-5225 Jülich, Germany 5Association EURATOM – Belgian State, Laboratory for Plasma Physics Koninklijke Militaire School – Ecole Royale Militaire Renaissancelaan 30 Avenue de la Renaissance B-1000, Brussels, Belgium 6ITER organisation, Fusion Science and Technology Department, Cadarache, 13108 St Paul Lez Durance, France 7Max-Planck-Institut für Plasmaphysik, Teilinstitut Greifswald, EURATOM-Assoziation, D-17491 Greifswald, Germany

2. Introduction Ip Wdia Prad Soft X-Ray Runaway plateau Thermal quench Current quench • Transient heat loads during disruptions are of great concern for plasma facing component integrity • Heat load sources during disruption are • Plasma thermal energy (thermal quench) • Radiation during thermal and current quench • Runaway electrons during current quench

3. Introduction • What we know • A significant part of the energy during the thermal quench goes onto the first wall, not onto the divertor [J. Paley et al. J. Nucl. Mater. 2005, P. Andrew et al. JNM 2007] • Heat load on the JET upper dump plate were characterised for different type of disruptions [G. Arnoux et al. NF 2009] • During massive injection of argon, RE impacts were observed on the JET upper dump plate [M. Lehnen et al., J. Nucl. Mater. 2009] • What we can learn from JET fast IR measurements • Heat loads onto the first wall during the thermal and current quench • What time scales? • Distribution onto PFCs: poloidal limiters, upper dump plate,… • RE impacts on the JET upper dump plate • Heat load pattern (distribution) • How much energy (magnetic and kinetic) transfered to the first wall during the RE loss?

4. Fast IR measurements CFC W • Fast time resolution: • DtIR≃1ms on first wall (Reduced IR view) • DtIR≃86ms on divertor outer target • Region of interest (pulse to pulse) • Outer limiter • Inner limiter • Upper dump plate • Data reduction • Poloidal profiles: T(x,y,t) → T(s,t) • Maximum temperature: T(x,y,t) → T(t) • Heat load profiles with THEODOR • T(s,t) → q(s,t) • On limiters: plasma wall interaction only, no radiation considered (mask) • On divertor, tile 5 only is considered

5. Heat loads due to plasma wall interaction during the thermal and current quench

6. TQ an CQ during low q disruptions tIR,in=4.9ms tIR,out=1.2ms tIR,div=0.9ms

7. Plasma wall interaction after TQ Inner limiter +4ms +6ms +8ms +10ms +12ms JPN77658

8. Plasma wall interaction after TQ Outer limiter +1ms +3ms +5ms +7ms +8ms +10ms JPN77660

9. Energy balance During thermal quench (TQ): Wth,TQ = Wrad + Wdiv + Wwall During current quench (CQ): Wmag = Wrad + Wdiv +Wwall with: Wwall = Wlim,in+ Wlim,out+ Wdum Plasma wall interaction only 0.5MJ < Wth,TQ < 2.3MJ Wmag≃ 9.1MJ Toroidal symmetry is assumed!

10. Heat load due to runaway electrons

11. RE impact on upper dump plate IRE=502kA ; Bt/Ip = 3.0/2.0 T1 T1 T5 T5 T2 T2 T3 T3 T4 T4 JPN76541, t=4.11ms JPN76541, t=18.58ms

12. RE impact on upper dump plate T1 T5 T2 T3 T4 RE interaction with dump plate dominated by geometry of PFCs JPN76541 JPN76532 JPN76533 JPN76534 JPN76535 JPN76536 IRE=173 kA IRE=502 kA IRE=425 kA IRE=285 kA IRE=360 kA IRE=502 kA T1

13. Temp. increase due to RE impact DTdum,av T1 T5 T2 T3 Imeas Ifit T4 JPN76541, t=18.6ms tRE≈2ms

14. RE energy load on upper dump plate Modelling [B. Bazylev, P1-98]: Energy load at the CFC surface: 0.5 < QRE < 3 MJ/m2 Current flowing into the CFC tile = IRE 60% of IRE get out of the tile => ~10% of magnetic energy dissipated into CFC tile

15. Conclusion • Heat loads onto the JET first wall have been measured during disruptions using enhanced, fast IR thermography • During TQ of low q disruptions, significant heat loads are measured on the poloidal limiters on a comparable time scale as that of the divertor • During CQ of low q disruptions, about 10% of the magnetic energy is transferred to the first wall via plasma wall interaction. • The RE interaction with the JET upper dump plate leads to very localised patterns, dominated by the wall geometry • Runaway electrons energy deposited on first wall scales with the square of RE current. • Modelling shows that about 10% of the magnetic energy is dissipated into the CFC tiles.

16. MGI and “natural” disruptions • 50% of Wdia,TQ is radiated prior to TQ • Power toouter divertor target just after TQ higher for “natural” disruption… • …in this example • What is Wdiv,5/Wdia,TQ for 35 pulses?

17. Energy load on outer divertor tile • Possible mitigation effect during TQ for Wdia,TQ < 1.5MJ • No clear difference with gas species in heated plasmas (Wdia,TQ > 1.5MJ) • What about heat load onto the first wall?