论文信息 - Ion cyclotron resonance frequency heating in JET during initial operations with the ITER-like wall - 字舞流文

Ion cyclotron resonance frequency heating in JET during initial operations with the ITER-like wall

In 2011/12, JET started operation with its new ITER-Like Wall (ILW) made of a tungsten (W) divertor and a beryllium (Be) main chamber wall. The impact of the new wall materials on the JET Ion Cyclotron Resonance Frequency (ICRF) operation is assessed and some important properties of JET plasmas heated with ICRF are highlighted. A ∼ 20% reduction of the antenna coupling resistance is observed with the ILW as compared with the JET carbon (JET-C) wall. Heat-fluxes on the protecting limiters close the antennas, quantified using Infra-Red thermography (maximum 4.5 MW/m2 in current drive phasing), are within the wall power load handling capabilities. A simple RF sheath rectification model using the antenna near-fields calculated with the TOPICA code can reproduce the heat-flux pattern around the antennas. ICRF heating results in larger tungsten and nickel (Ni) contents in the plasma and in a larger core radiation when compared to Neutral Beam Injection (NBI) heating. The location of the tungsten ICRF specific source could not be identified but some experimental observations indicate that main-chamber W components could be an important impurity source: for example, the divertor W influx deduced from spectroscopy is comparable when using RF or NBI at same power and comparable divertor conditions, and Be evaporation in the main chamber results in a strong reduction of the impurity level. In L-mode plasmas, the ICRF specific high-Z impurity content decreased when operating at higher plasma density and when increasing the hydrogen concentration from 5% to 15%. Despite the higher plasma bulk radiation, ICRF exhibited overall good plasma heating performance; the power is typically deposited at the plasma centre while the radiation is mainly from the outer part of the plasma bulk. Application of ICRF heating in H-mode plasmas has started, and the beneficial effect of ICRF central electron heating to prevent W accumulation in the plasma core has been observed.

Daniele Milanesio | C. C. Klepper | Ernesto Lerche | L. Colas | A. Sirinelli | Jan Mlynar | S. Brezinsek | A. Czarnecka | P. Drewelow | A. G. Meigs | P. Jacquet | I. Monakhov | Jet-Efda Contributors | G. Arnoux | V. Bobkov | M-L Mayoral | M. Brix | Stéphane Devaux | J. Contributors | T. Pütterich | S. Brezinsek | M. Mayoral | L. Colas | A. Sirinelli | A. Meigs | P. Drewelow | A. Czarnecka | M. Brix | G. Arnoux | S. Devaux | V. Bobkov | E. Lerche | M. Graham | P. Jacquet | C. Klepper | I. Monakhov | D. Milanesio | Th. Pütterich | M. E. Graham | D. Van-Eester | A. L. Campergue | J. Mlynar | A. Campergue | D. Van-Eester

[1] O. Sauter,et al. Numerical analysis of JET discharges with the European Transport Simulator , 2013 .

[2] Jet Efda Contributors,et al. Implementation of load resilient ion cyclotron resonant frequency (ICRF) systems to couple high levels of ICRF power to ELMy H-mode plasmas in JET , 2012 .

[3] J. Contributors,et al. Comparison of ICRF and NBI heated plasmas performances in the JET ITER-like wall , 2014 .

[4] M. Beurskens,et al. Impact of carbon and tungsten as divertor materials on the scrape-off layer conditions in JET , 2013 .

[5] L. Colas,et al. Edge plasma density convection during ion cyclotron resonance heating on Tore Supra , 2002 .

[6] Daniele Milanesio,et al. Estimated RF sheath power fluxes on ITER plasma facing components , 2009 .

[7] A. Scarabosio,et al. Improvement of ICRF antenna loading by local gas injection on ASDEX Upgrade , 2012 .

[8] L. L. Lao,et al. Equilibrium analysis of current profiles in tokamaks , 1990 .

[9] F Durodie,et al. Design and operations of a load-tolerant external conjugate-T matching system for the A2 ICRH antennas at JET , 2013, 1309.4644.

[10] F. Jenko,et al. Particle and impurity transport in the Axial Symmetric Divertor Experiment Upgrade and the Joint European Torus, experimental observations and theoretical understanding , 2007 .

[11] E. Villedieu,et al. Overview of the ITER-like wall project , 2007 .

[12] Jet Efda Contributors,et al. First operation with the JET International Thermonuclear Experimental Reactor-like wall , 2013 .

[13] Jet Efda Contributors,et al. RF sheath-enhanced beryllium sources at JET’s ICRH antennas , 2013 .

[14] G. Bateman,et al. The tokamak Monte Carlo fast ion module NUBEAM in the National Transport Code Collaboration library , 2004 .

[15] A. S. Kaye,et al. Present and future JET ICRF antennae , 1994 .

[16] J. Contributors,et al. Impact of minority concentration on fundamental (H)D ICRF heating performance in JET-ILW , 2013 .

[17] O. Meneghini,et al. A multi-cavity approach for enhanced efficiency in TOPICA RF antenna code , 2009 .

[18] Jet Efda Contributors,et al. Observations on the W-transport in the core plasma of JET and ASDEX Upgrade , 2013 .

[19] J. Contributors,et al. Deuterium Balmer/Stark spectroscopy and impurity profiles: First results from mirror-link divertor spectroscopy system on the JET ITER-like wall , 2013, 1307.6985.

[20] D. McCune,et al. New techniques for calculating heat and particle source rates due to neutral beam injection in axisymmetric tokamaks , 1981 .

[21] J. Contributors,et al. Effect of the minority concentration on ion cyclotron resonance heating in presence of the ITER-like wall in JET , 2014 .

[22] J. Contributors,et al. Characterisation of local ICRF heat loads on the JET ILW , 2013, 1306.6778.

[23] P. Thomas,et al. Upgrade of the infrared camera diagnostics for the JET ITER-like wall divertor. , 2012, The Review of scientific instruments.

[24] J. Contributors,et al. Impurity production from the ion cyclotron resonance heating antennas in JET , 2012 .

[25] J. Contributors,et al. Spectroscopic investigation of heavy impurity behaviour during ICRH with the JET ITER-like wall , 2014 .

[26] J. Contributors,et al. Statistical comparison of ICRF and NBI heating performance in JET-ILW L-mode plasmas , 2014 .

[27] Jet Efda Contributors,et al. Improved break-in-slope analysis of the plasma energy response in tokamaks , 2008 .

[28] Daniele Milanesio,et al. Radio-frequency sheaths physics: Experimental characterization on Tore Supra and related self-consistent modeling , 2014 .

[29] M. Brambilla,et al. Influence of an evanescence layer in front of the antenna on the coupling efficiency of ion cyclotron waves , 2005 .

[30] R. Neu,et al. ICRF specific plasma wall interactions in JET with the ITER-like wall , 2013 .

[31] S. Coda,et al. Control of magnetohydrodynamic stability by phase space engineering of energetic ions in tokamak plasmas , 2012, Nature Communications.

[32] A. Taroni,et al. CORRIGENDUM: The influence of isotope mass, edge magnetic shear and input power on high density ELMy H modes in JET , 1999 .

[33] Characterization of local heat fluxes around ICRF antennas on JET , 2014 .

[34] Z. Vizvary,et al. Heat loads on JET plasma facing components from ICRF and LH wave absorption in the SOL , 2011 .