CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority Internal Transport Barriers and Improved Confinement in Tokamaks (Three possible.

Slides:

Advertisements

Similar presentations

Short wavelength ion temperature gradient driven instability in toroidal plasmas Zhe Gao, a) H. Sanuki, b) K. Itoh b) and J. Q. Dong c) a) Department of.

Advertisements

Simulations of the core/SOL transition of a tokamak plasma Frederic Schwander,Ph. Ghendrih, Y. Sarazin IRFM/CEA Cadarache G. Ciraolo, E. Serre, L. Isoardi,

RF Control of Tokamak Plasma Transport

Two-dimensional Structure and Particle Pinch in a Tokamak H-mode

INTRODUCTION OF WAVE-PARTICLE RESONANCE IN TOKAMAKS J.Q. Dong Southwestern Institute of Physics Chengdu, China International School on Plasma Turbulence.

Alfvén-cyclotron wave mode structure: linear and nonlinear behavior J. A. Araneda 1, H. Astudillo 1, and E. Marsch 2 1 Departamento de Física, Universidad.

1 G.T. Hoang, 20th IAEA Fusion Energy Conference Euratom Turbulent Particle Transport in Tore Supra G.T. Hoang, J.F. Artaud, C. Bourdelle, X. Garbet and.

Momentum transport and flow shear suppression of turbulence in tokamaks Michael Barnes University of Oxford Culham Centre for Fusion Energy Michael Barnes.

Modeling Generation and Nonlinear Evolution of Plasma Turbulence for Radiation Belt Remediation Center for Space Science & Engineering Research Virginia.

1 Global Gyrokinetic Simulations of Toroidal ETG Mode in Reversed Shear Tokamaks Y. Idomura, S. Tokuda, and Y. Kishimoto Y. Idomura 1), S. Tokuda 1), and.

F. Nabais - Vilamoura - November 2004 Internal kink mode stability in the presence of ICRH driven fast ions populations F. Nabais, D. Borba, M. Mantsinen,

Some results / ideas on the effect of flows D. Strintzi, C. Angioni, A. Bottino, A.G. Peeters.

The Stability of Internal Transport Barriers to MHD Ballooning Modes and Drift Waves: a Formalism for Low Magnetic Shear and for Velocity Shear The Stability.

Large-scale structures in gyrofluid ETG/ITG turbulence and ion/electron transport 20 th IAEA Fusion Energy Conference, Vilamoura, Portugal, November.

Intermittent Transport and Relaxation Oscillations of Nonlinear Reduced Models for Fusion Plasmas S. Hamaguchi, 1 K. Takeda, 2 A. Bierwage, 2 S. Tsurimaki,

Non-diffusive terms of momentum transport as a driving force for spontaneous rotation in toroidal plasmas K.Ida, M.Yoshinuma, LHD experimental group National.

Turbulent transport in collisionless plasmas: eddy mixing or wave-particle decorrelation? Z. Lin Y. Nishimura, I. Holod, W. L. Zhang, Y. Xiao, L. Chen.

N EOCLASSICAL T OROIDAL A NGULAR M OMENTUM T RANSPORT IN A R OTATING I MPURE P LASMA S. Newton & P. Helander This work was funded jointly by EURATOM and.

Computer simulations of fast frequency sweeping mode in JT-60U and fishbone instability Y. Todo (NIFS) Y. Shiozaki (Graduate Univ. Advanced Studies) K.

Calculations of Gyrokinetic Microturbulence and Transport for NSTX and C-MOD H-modes Martha Redi Princeton Plasma Physics Laboratory Transport Task Force.

TH/7-2 Radial Localization of Alfven Eigenmodes and Zonal Field Generation Z. Lin University of California, Irvine Fusion Simulation Center, Peking University.

Microstability analysis of e-ITBs in high density FTU plasmas 1)Associazione EURATOM-ENEA sulla fusione, C.R. Frascati, C.P , Frascati, Italy.

Challenging problems in kinetic simulation of turbulence and transport in tokamaks Yang Chen Center for Integrated Plasma Studies University of Colorado.

Excitation of ion temperature gradient and trapped electron modes in HL-2A tokamak The 3 th Annual Workshop on Fusion Simulation and Theory, Hefei, March.

HAGIS Code Lynton Appel … on behalf of Simon Pinches and the HAGIS users CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority.

ASIPP On the observation of small scale turbulence on HT-7 tokamak* Tao Zhang**, Yadong Li, Shiyao Lin, Xiang Gao, Junyu Zhao, Qiang Xu Institute of Plasma.

11 Role of Non-resonant Modes in Zonal Flows and Intrinsic Rotation Generation Role of Non-resonant Modes in Zonal Flows and Intrinsic Rotation Generation.

Research activity on the T-10 tokamak G. Kirnev on behalf of T-10 team Nuclear Fusion Institute, RRC “Kurchatov Institute”, Moscow , Russia.

Dynamics of ITG driven turbulence in the presence of a large spatial scale vortex flow Zheng-Xiong Wang, 1 J. Q. Li, 1 J. Q. Dong, 2 and Y. Kishimoto 1.

Electron behaviour in three-dimensional collisionless magnetic reconnection A. Perona 1, D. Borgogno 2, D. Grasso 2,3 1 CFSA, Department of Physics, University.

Nonlinear interactions between micro-turbulence and macro-scale MHD A. Ishizawa, N. Nakajima, M. Okamoto, J. Ramos* National Institute for Fusion Science.

Comparison of Ion Thermal Transport From GLF23 and Weiland Models Under ITER Conditions A. H. Kritz 1 Christopher M. Wolfe 1 F. Halpern 1, G. Bateman 1,

Tearing Parity Microturbulent Drift Modes on NSTX Martha Redi NSTX Results Review 9/21/04 W. Dorland, U. Maryland, J. Baumgaertel, U. Washington (SULI)

1 Turbulent Generation of Large Scale Magnetic Fields in Unmagnetized Plasma Vladimir P.Pavlenko Uppsala University, Uppsala, Sweden.

Electron inertial effects & particle acceleration at magnetic X-points Presented by K G McClements 1 Other contributors: A Thyagaraja 1, B Hamilton 2,

Hybrid MHD-Gyrokinetic Simulations for Fusion Reseach G. Vlad, S. Briguglio, G. Fogaccia Associazione EURATOM-ENEA, Frascati, (Rome) Italy Introduction.

1Peter de Vries – ITBs and Rotational Shear – 18 February 2010 – Oxford Plasma Theory Group P.C. de Vries JET-EFDA Culham Science Centre Abingdon OX14.

Transport in three-dimensional magnetic field: examples from JT-60U and LHD Katsumi Ida and LHD experiment group and JT-60 group 14th IEA-RFP Workshop.

Kinetic Alfvén turbulence driven by MHD turbulent cascade Yuriy Voitenko & Space Physics team Belgian Institute for Space Aeronomy, Brussels, Belgium.

STUDIES OF NONLINEAR RESISTIVE AND EXTENDED MHD IN ADVANCED TOKAMAKS USING THE NIMROD CODE D. D. Schnack*, T. A. Gianakon**, S. E. Kruger*, and A. Tarditi*

Chalmers University of Technology Simulations of the formation of transport barriers including the generation of poloidal spinup due to turbulence J. Weiland.

RFX-mod Program Workshop, Padova, January Current filaments in turbulent magnetized plasmas E. Martines.

CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority Challenges for Fusion Theory and Explosive Behaviour in Plasmas Steve Cowley,

The influence of non-resonant perturbation fields: Modelling results and Proposals for TEXTOR experiments S. Günter, V. Igochine, K. Lackner, Q. Yu IPP.

Summary on transport IAEA Technical Meeting, Trieste Italy Presented by A.G. Peeters.

Intermittent Oscillations Generated by ITG-driven Turbulence US-Japan JIFT Workshop December 15 th -17 th, 2003 Kyoto University Kazuo Takeda, Sadruddin.

TTF M. Ottaviani Euratom TORE SUPRA Overview of progress in transport theory and in the understanding of the scaling laws M. Ottaviani EURATOM-CEA,

Turbulent Convection and Anomalous Cross-Field Transport in Mirror Plasmas V.P. Pastukhov and N.V. Chudin.

21st IAEA Fusion Energy Conf. Chengdu, China, Oct.16-21, /17 Gyrokinetic Theory and Simulation of Zonal Flows and Turbulence in Helical Systems T.-H.

IEA RFP Workshop, April Padova Internal electron transport barriers in RFX-mod helical equilibria R. Lorenzini on behalf of the RFX-mod team.

Electrostatic fluctuations at short scales in the solar-wind turbulent cascade. Francesco Valentini Dipartimento di Fisica and CNISM, Università della.

1 Peter de Vries – ITPA T meeting Culham – March 2010 P.C. de Vries 1,2, T.W. Versloot 1, A. Salmi 3, M-D. Hua 4, D.H. Howell 2, C. Giroud 2, V. Parail.

Kinetic-Fluid Model for Modeling Fast Ion Driven Instabilities C. Z. Cheng, N. Gorelenkov and E. Belova Princeton Plasma Physics Laboratory Princeton University.

Simulation of Turbulence in FTU M. Romanelli, M De Benedetti, A Thyagaraja* *UKAEA, Culham Sciance Centre, UK Associazione.

1 ASIPP Sawtooth Stabilization by Barely Trapped Energetic Electrons Produced by ECRH Zhou Deng, Wang Shaojie, Zhang Cheng Institute of Plasma Physics,

IAEA-TM 02/03/2005 1G. Falchetto DRFC, CEA-Cadarache Association EURATOM-CEA NON-LINEAR FLUID SIMULATIONS of THE EFFECT of ROTATION on ION HEAT TURBULENT.

Interaction between vortex flow and microturbulence Zheng-Xiong Wang （王正汹） Dalian University of Technology, Dalian, China West Lake International Symposium.

Gyrokinetic Calculations of Microturbulence and Transport for NSTX and Alcator C-MOD H-modes Martha Redi Princeton Plasma Physics Laboratory NSTX Physics.

Plan V. Rozhansky, E. Kaveeva St.Petersburg State Polytechnical University, , Polytechnicheskaya 29, St.Petersburg, Russia Poloidal and Toroidal.

TH/7-1Multi-phase Simulation of Alfvén Eigenmodes and Fast Ion Distribution Flattening in DIII-D Experiment Y. Todo (NIFS, SOKENDAI) M. A. Van Zeeland.

Energetic ion excited long-lasting “sword” modes in tokamak plasmas with low magnetic shear Speaker:RuiBin Zhang Advisor:Xiaogang Wang School of Physics,

FPT Discussions on Current Research Topics Z. Lin University of California, Irvine, California 92697, USA.

Mechanisms for losses during Edge Localised modes (ELMs)

An overview of turbulent transport in tokamaks

Gyrokinetic Simulation of Multimode Plasma Turbulence

Investigation of triggering mechanisms for internal transport barriers in Alcator C-Mod K. Zhurovich C. Fiore, D. Ernst, P. Bonoli, M. Greenwald, A. Hubbard,

Influence of energetic ions on neoclassical tearing modes

T. Morisaki1,3 and the LHD Experiment Group

T. Morisaki1,3 and the LHD Experiment Group

H. Nakano1,3, S. Murakami5, K. Ida1,3, M. Yoshinuma1,3, S. Ohdachi1,3,

Presentation transcript:

CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority Internal Transport Barriers and Improved Confinement in Tokamaks (Three possible trigger mechanisms) M Romanelli 1, F. Militello 1, G. Szepesi 1,2, A. Zocco 1 1 EURATOM/CCFE Fusion Association, UK 2 University of Warwick, UK Acknowledgments: F Crisanti, G Mazzitelli, F Zonca (ENEA), J Hastie and J Connor (CCFE) 14 th European Fusion Theory Conference, Frascati, Italy, September This work is funded by RCUK Energy Programme and EURATOM

Michele Romanelli – EFTC20112September Introduction Many different mechanisms can be responsible for improved confinement in tokamak plasmas. In this presentation I will introduce three such mechanisms that could concur or play an independent role in the formation of an Internal Transport Barrier (ITB) or lead to improved confinement of particles and heat  Fast ion induced alpha stabilization: the role of fast ion pressure in stabilizing the thermal-ion gradient driven modes is discussed in the context of e-m mode stability.  Zonal perturbations: the interplay between drift-Alfvén wave turbulence and electromagnetic zonal perturbation is examined in the framework of a parametric instability analysis  Impurities: improved electron confinement along with the expulsion of impurities is explained in terms of change in the turbulent spectrum and turbulent driven particle fluxes in the presence of a light impurity

Michele Romanelli – EFTC20113September Introduction Discussion of triggering mechanisms:  Fast ion induced alpha stabilization : the role of fast ion pressure in stabilizing the thermal-ion gradient driven modes is discussed in the context of EM mode stability.  Zonal perturbations: the interplay between drift-Alfvén wave turbulence and electromagnetic zonal perturbation is examined in the framework of a parametric instability analysis  Impurities: improved electron confinement along with the expulsion of impurities is explained in terms of change in the turbulent spectrum and turbulent driven particle fluxes in the presence of a light impurity

Michele Romanelli – EFTC20114September Flat region 3.5 m t 48.6 s s (1 s time evolution) 20% of central temperature increase (same heating power) due to ITB q Fast ions α- stabilization T i [eV]  Microstability analysis of a JET hybrid discharge with GS2 (EM) JET #59137

Michele Romanelli – EFTC20115September Fast ions α - stabilization  Thermal profiles corresponding to t=10s (gradients have been taken at R=3.5 m)  Density profiles of NBI+ICRH fast H minority

Michele Romanelli – EFTC20116September Fast ions α - stabilization (EM)  Change of the long wavelength spectra when increasing the temperature of the minority species  Increasing α -> complete ITG stabilization for K  ρ i ≥0.6 -> EM modes

Michele Romanelli – EFTC20117September Fast ions α - stabilization (electrostatic)  Effect of changing L nfast and s' in the electrostatic limit  In the electrostatic limit α-stabilization is less effective (requires much higher values of α to stabilize ITG at given s and L nfast

Michele Romanelli – EFTC20118September Fast ions α - stabilization (EM). Microtering arise the presence of wave particle interaction as can be seen from the parallel component of Ohm’s equation, given by the parallel gradient of equation: The drive of the instability is the gradient of the electron temperature. The mode is destabilized by increasing the ion pressure gradient, at constant electron temperature and density gradient. In general, the parallel electric field will be non-zero and will have a direct contribution from the parallel vector potential, second term on the LHS, and from the non-adiabatic part of the distribution functions.  [21] Zonca F et al 1999 Phys. Plasmas  At high T H micro tearing modes are found to replace ITG-TEM for K  ρ i ≥0.6

Michele Romanelli – EFTC20119September Fast ions α - stabilization (EM)  By increasing the energy of the hydrogen minority the short wavelength modes (μT) are stabilized however for α>0.4 the long wavelength AITG modes are destabilized.

Michele Romanelli – EFTC201110September Introduction Discussion of triggering mechanisms:  Fast ion induced alpha stabilization: the role of fast ion pressure in stabilizing the thermal-ion gradient driven modes is discussed in the context of e-m mode stability.  Zonal perturbations: the interplay between drift-Alfvén wave turbulence and electromagnetic zonal perturbation is examined in the framework of a parametric instability analysis  Impurities: improved electron confinement along with the expulsion of impurities is explained in terms of change in the turbulent spectrum and turbulent driven particle fluxes in the presence of a light impurity

Michele Romanelli – EFTC201111September Introduction The ITB can be caused by a region of plasma where the m=0, n=0 velocity shear is large, since there the correlation length of the turbulent eddies is reduced. Zonal Flows are m=0, n=0 secondary instabilities (i.e. they are linearly stable) which can arise from the interaction of drift waves. The generation of the Zonal Flows (and hence of the ITB) can be studied with a parametric instability approach. Details in Militello, Romanelli, Connor and Hastie, Nuclear Fusion (2011).

Michele Romanelli – EFTC201112September Model We study the problem with a fluid model in a slab: We assume T i =0, T e =const, small finite  and negligible dissipation. The time is normalized to the Alfven time and the length to a macroscopic size. d e is the electron skin depth and  s is the ion sound Larmor radius.  radial profiles

Michele Romanelli – EFTC201113September When density gradients are present, in the system appear: –Drift-Alfven waves (primary “instability”, linear): –Zonal perturbations (secondary instability coupled through sidebands, quasi-linear): Primary and secondary instabilities primary secondary

Michele Romanelli – EFTC201114September Normalized frequency of the Zonal perturbation Dispersion relation Linearizing the system around an equilibrium with a large primary instability leads to a (huge!) dispersion relation for the secondary instability (i.e. the Zonal Perturbation). Normalized growth rate of the Zonal perturbation Militello, Romanelli, Connor and Hastie, NF (2011)

Michele Romanelli – EFTC201115September Normalized frequency of the Zonal perturbation Dispersion relation Linearizing the system around an equilibrium with a large primary instability leads to a (huge!) dispersion relation for the secondary instability (i.e. the Zonal Perturbation). Normalized growth rate of the Zonal perturbation Electrostatic Branch Electromagnetic branch Solid lines: Guzdar et al. PRL (2001) Militello, Romanelli, Connor and Hastie, NF (2011)

Michele Romanelli – EFTC201116September Not only Zonal flows Zonal magnetic fields (with d e ≠0) and zonal density can be generated as well (new result). The zonal Fields can provide a drive for the Tearing mode. (Militello et al., PoP 2009) Zonal densityZonal fields

Michele Romanelli – EFTC201117September ITB criterion As noted before, self-sustained Zonal Perturbations appear for >1. Around a resonant surface: We can define a width around the surface where the condition is always met: To shear the eddies, x cr must be larger than  s : or equivalently:

Michele Romanelli – EFTC201118September ITB criterion II The criterion is a necessary condition but it is not sufficient (it does not say anything about the nonlinear evolution). Assumption: a barrier survives if a sufficient amount of energy goes from the turbulence to the zonal perturbation. Only the resonant modes transfer energy to the zonal perturbation. Low order helicities have more resonant modes. Conclusion: an ITB forms and survives when a low order rational surface enters the palsma and:

Michele Romanelli – EFTC201119September Introduction Discussion of triggering mechanisms:  Fast ion induced alpha stabilization: the role of fast ion pressure in stabilizing the thermal-ion gradient driven modes is discussed in the context of e-m mode stability.  Zonal currents: the interplay between drift-Alfvén wave turbulence and electromagnetic zonal perturbation is examined in the framework of a parametric instability analysis  Impurities: improved electron confinement along with the expulsion of impurities is explained in terms of change in the turbulent spectrum and turbulent driven particle fluxes in the presence of a light impurity

Michele Romanelli – EFTC2011September Impurity triggered inward e - pinch Turbulent particle fluxes (in the simplest case of electrostatic turbulence) arise from the phase shift between electrostatic potential fluctuations and density fluctuations  In the presence of impurities the electron and deuterium fluxes are decoupled; the phase shift between electron-deuterium density fluctuations and electrostatic potential might become significantly different and inward pinches can appear. In strongly electron driven turbulence, impurities are expected to stabilise the ETG modes [ Reshko M. and Roach C.M Plasma Phys. Control. Fusion ]  Impurity ions will change the turbulence spectrum moving the peak toward higher

Michele Romanelli – EFTC201121September Plasma parameters Plasma parameters have been taken from an FTU discharge where in the presence of Lithium Limiter improved confinement and strong density peaking was observed  Mazzitelli G. et al 2011 Nucl. Fusion  A. Peeters et al, Computer Physics Communications 180 (2009) 2650–2672 The effect of one light impurity (Li) species on (D-e-) plasma microstability has been investigated with the flux tube gyrokinetic code GKW.

Michele Romanelli – EFTC201122September Impurity effect on spectrum (GKW)

Michele Romanelli – EFTC201123September Linear particle fluxes

Michele Romanelli – EFTC201124September Linear particle fluxes  The change in sign of the fluxes coincides with the change of unstable mode from ITG to TEM  Extensive parametric scan is presented in M Romanelli, G Szepesi et al Nucl. Fusion 51 (2011) (9pp)

Michele Romanelli – EFTC201125September Nonlinear particle fluxes at r/a=0.6, t=0.3s

Michele Romanelli – EFTC201126September Summary Different triggering mechanisms can be responsible for the transition to improved confinement in tokamak plasmas. In this presentation three such mechanisms have been dsicussed  Fast ions induced α - stabilization: M Romanelli, A Zocco et al Plasma Phys. Control. Fusion 52 (2010)  Criteria for ITB formation in low shear plasmas: F Militello, M Romanelli, J Connor and J Hastie, Nuclear Fusion (2011).  Impurity induced inward deuterium and electron pinch: M Romanelli, G Szepesi et al Nucl. Fusion 51 (2011) (9pp) This work is funded by RCUK Energy Programme and EURATOM