8th IAEA Technical Meeting on

Slides:

Advertisements

Similar presentations

Control of Magnetic Chaos & Self-Organization John Sarff for MST Group CMSO General Meeting Madison, WI August 4-6, 2004.

Advertisements

Glenn Bateman Lehigh University Physics Department

W. Heidbrink, G. Kramer, R. Nazikian, M. Van Zeeland, M. Austin, H. Berk, K. Burrell, N. Gorelenkov, Y. Luo, G. McKee, T. Rhodes, G. Wang, and the DIII-D.

Lecture Series in Energetic Particle Physics of Fusion Plasmas Guoyong Fu Princeton Plasma Physics Laboratory Princeton University Princeton, NJ 08543,

TAE-EP Interaction in ARIES ACT-I K. Ghantous, N.N Gorelenkov PPPL ARIES Project Meeting,, 26 Sept

6 th ITPA MHD Topical Group Meeting combined with W60 IEA Workshop on Burning Plasmas Session II MHD Stability and Fast Particle Confinement General scope.

Cyclic MHD Instabilities Hartmut Zohm MPI für Plasmaphysik, EURATOM Association Seminar talk at the ‚Advanced Course‘ of EU PhD Network, Garching, September.

Nonlinear Simulations of ELMs with NIMROD D.P. Brennan Massachussetts Institute of Technology Cambridge, MA S.E. Kruger Tech-X Corp, Boulder, CO A. Pankin,

Lecture Series in Energetic Particle Physics of Fusion Plasmas

Energetic Particle Physics in Tokamak Plasmas Guoyong Fu Princeton Plasma Physics Laboratory Princeton University Princeton, NJ 08543, USA 6 th Workshop.

Kinetic Theories of Geodesic Acoustic Modes in Toroidal Plasmas Zhiyong Qiu, F. Zonca and L. Chen IFTS, May 2010.

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

Discrete Alfven Eigenmodes Shuang-hui Hu College of Sci, Guizhou Univ, Guiyang Liu Chen Dept of Phys & Astr, UC Irvine Supported by DOE and NSF.

Fast ion effects on fishbones and n=1 kinks in JET simulated by a non-perturbative NOVA-KN code TH/5-2Rb N.N. Gorelenkov 1), C.Z.Cheng 1), V.G. Kiptily.

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

TH/3-1Ra Nonperturbative Effects of Energetic Ions on Alfvén Eigenmodes by Y. Todo et al. EX/5-4Rb Configuration Dependence of Energetic Ion Driven Alfven.

1 Phase Space Instability with Frequency Sweeping H. L. Berk and D. Yu. Eremin Institute for Fusion Studies Presented at IAEA Workshop Oct

D. Borba 1 21 st IAEA Fusion Energy Conference, Chengdu China 21 st October 2006 Excitation of Alfvén eigenmodes with sub-Alfvénic neutral beam ions in.

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

SIMULATION OF A HIGH-  DISRUPTION IN DIII-D SHOT #87009 S. E. Kruger and D. D. Schnack Science Applications International Corp. San Diego, CA USA.

Nonlinear Frequency Chirping of Alfven Eigenmode in Toroidal Plasmas Huasen Zhang 1,2 1 Fusion Simulation Center, Peking University, Beijing , China.

Kinetic Effects on the Linear and Nonlinear Stability Properties of Field- Reversed Configurations E. V. Belova PPPL 2003 APS DPP Meeting, October 2003.

J A Snipes, 6 th ITPA MHD Topical Group Meeting, Tarragona, Spain 4 – 6 July 2005 TAE Damping Rates on Alcator C-Mod Compared with Nova-K J A Snipes *,

Hybrid Simulations of Energetic Particle-driven Instabilities in Toroidal Plasmas Guo-Yong Fu In collaboration with J. Breslau, J. Chen, E. Fredrickson,

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

The Role of Damping in Stable and Unstable Alfvén Eigenmodes S. D. Pinches 1, A. Könies 2, Ph. Lauber 1 H.L.Berk 3, S.E.Sharapov 4 and M.Gryaznavich 4.

Particle Distribution Modification by TAE mode and Resonant Particle Orbits POSTECH 1, NFRI 1,2 M.H.Woo 1, C.M.Ryu 1, T.N.Rhee 1,,2.

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.

Chalmers University of Technology Szczecin, 23 March 2006 Meeting with Dr. B. Green Dr. B. Green (Euratom) and Prof. A. Gałkowski (Association Euratom-IPPLM)

Recent advances in wave kinetics

Transition from ” True” Modes to Quasimodes for Radially Extended Perturbations Page 1 Nonlinear Consequences of Energetic Particle Instabilities Boris.

Modeling Beam Ion Relaxation with application to DIII-D K.Ghantous, N.N. Gorelenkov PPPL, 2012.

Summary of MHD Topics 2nd IAEA Technical Meeting Theory of Plasma Instabilities Howard Wilson.

Lecture Series in Energetic Particle Physics of Fusion Plasmas

Stability Properties of Field-Reversed Configurations (FRC) E. V. Belova PPPL 2003 International Sherwood Fusion Theory Conference Corpus Christi, TX,

(National Institute for Fusion Science, Japan)

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

Contribution of KIT to LHD Topics from collaboration research on MHD phenomena in LHD S. Masamune, K.Y. Watanabe 1), S. Sakakibara 1), Y. Takemura, KIT.

Lecture Series in Energetic Particle Physics of Fusion Plasmas Guoyong Fu Princeton Plasma Physics Laboratory Princeton University Princeton, NJ 08543,

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*

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

1 A Proposal for a SWIM Slow-MHD 3D Coupled Calculation of the Sawtooth Cycle in the Presence of Energetic Particles Josh Breslau Guo-Yong Fu S. C. Jardin.

1 Stability Studies Plans (FY11) E. Fredrickson, For the NCSX Team NCSX Research Forum Dec. 7, 2006 NCSX.

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

Simulations of NBI-driven Global Alfven Eigenmodes in NSTX E. V. Belova, N. N. Gorelenkov, C. Z. Cheng (PPPL) NSTX Results Forum, PPPL July 2006 Motivation:

Y. Kishimoto 1,2), K. Miki 1), N. Miyato 2), J.Q.Li 1), J. Anderson 1) 21 st IAEA Fusion Energy Conference IAEA-CN-149-PD2 (Post deadline paper) October.

Neoclassical Effects in the Theory of Magnetic Islands: Neoclassical Tearing Modes and more A. Smolyakov* University of Saskatchewan, Saskatoon, Canada,

Simulations of turbulent plasma heating by powerful electron beams Timofeev I.V., Terekhov A.V.

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

Processes in Protoplanetary Disks Phil Armitage Colorado.

Simulations of Energetic Particle Modes In Spherical Torus G.Y. Fu, J. Breslau, J. Chen, E. Fredrickson, S. Jardin, W. Park Princeton Plasma Physics Laboratory.

Nonlinear Simulations of Energetic Particle-driven Modes in Tokamaks Guoyong Fu Princeton Plasma Physics Laboratory Princeton, NJ, USA In collaboration.

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.

Energetic Particles Interaction with the Non-resonant Internal Kink in Spherical Tokamaks Feng Wang*, G.Y. Fu**, J.A. Breslau**, E.D. Fredrickson**, J.Y.

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.

6 th ITPA MHD Topical Group Meeting combined with W60 IEA Workshop on Burning Plasmas Summary Session II MHD Stability and Fast Particle Confinement chaired.

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

NIMROD Simulations of a DIII-D Plasma Disruption S. Kruger, D. Schnack (SAIC) April 27, 2004 Sherwood Fusion Theory Meeting, Missoula, MT.

G.Y. Park 1, S.S. Kim 1, T. Rhee 1, H.G. Jhang 1, P.H. Diamond 1,2, I. Cziegler 2, G. Tynan 2, and X.Q. Xu 3 1 National Fusion Research Institute, Korea.

U NIVERSITY OF S CIENCE AND T ECHNOLOGY OF C HINA Influence of ion orbit width on threshold of neoclassical tearing modes Huishan Cai 1, Ding Li 2, Jintao.

Reconnection Process in Sawtooth Crash in the Core of Tokamak Plasmas Hyeon K. Park Ulsan National Institute of Science and Technology, Ulsan, Korea National.

M. Fitzgerald, S.E. Sharapov, P. Rodrigues2, D. Borba2

Huishan Cai, Jintao Cao, Ding Li

Influence of energetic ions on neoclassical tearing modes

27th IAEA Fusion Energy Conference, October 2018, Gandhinagar, India

Stabilization of m/n=1/1 fishbone by ECRH

20th IAEA Fusion Energy Conference,

E.M. Bass1 and R.E. Waltz2 1UC San Diego 2General Atomics

Ioffe Summary Fast MHD oscillations observed on the TUMAN-3M in absence of energetic ions Bursts of the oscillations correlate with saw-tooth crashes and.

Alfvén eigenmodes (AE) degrade fast-ion confinement in high βN, steady-state scenarios W.W. (Bill) Heidbrink1 with J. Ferron,2 C. Holcomb,3 M. Van Zeeland2,

Presentation transcript:

8th IAEA Technical Meeting on Energetic Particles in Magnetic Confinement Systems 6-8 October 2003, San Diego, California, USA Selected Issues in Energetic Particle Theory Presented by Boris Breizman In collaboration with H. Berk, J. Candy, A. Ödblom, V. Pastukhov, M. Pekker, N. Petviashvili, S. Pinches, S. Sharapov, Y. Todo, and JET-EFDA contributors

Outline Predictive capabilities of linear theory and simulations Near-threshold nonlinear regimes Remaining mysteries in Alfvén Cascade observations Nonlinear modification of Alfvén wave damping Interplay of kinetic and fluid resonances Convective and diffusive scenarios for global transport Transport barriers for energetic particles Remarks about next steps 2

Products of linear theory Mode frequencies Frequencies are robust (for perturbative modes) and easy to measure in experimens Mode structure Robust, measurable and usable in nonlinear theory (for perturbative modes) Growth rates Energetic particle drive can be calculated reliably but it changes quickly due to nonlinear effects Damping rates Except for collisional damping, the damping rates from the background plasma are exponentially sensitive to plasma parameters (ion Landau damping, radiative damping, continuum damping) 3

Things to do in linear analysis Fast particle phase space study in presence of linearly unstable modes to find robust conditions for global diffusion Issue: possible partial depletion of phase space Comprehensive sensitivity study of instability boundaries to plasma parameters Mode suppression over a sufficiently broad radial interval to create a transport barrier for energetic particles Careful assessment of edge effects (boundary conditions for the modes, particle orbits, etc.) 4

Near-threshold nonlinear regimes Macroscopic plasma parameters typically evolve slowly on instability time-scale. Perturbation technique is adequate near instability threshold. Identification of soft and hard nonlinear regimes is crucial (does the unstable system move towards marginal stability?). Bifurcations in single-mode saturation can be analyzed. Formation of long-lived nonlinear structures is likely. Multi-mode scenarios with marginal stability and possibly transport barriers are of interest. 5

Alfvén Cascades (initial step) IFS-JET collaboration: PRL 87, 185002-1 (2001) Frequency initially below TAE gap, while safety factor decreases in time Frequency sweeps predominantly upward, usually not downward Frequency signals are repetitive for a large number of n-values Sometimes frequency merges into the TAE gap 6

Transition from Alfvén Cascades to TAEs (2002 advance) Mode structure Mode tail near continuum resonance (zoomed) 200 200 q0=2.915 200 200 q0=2.875 40 40 q0=2.86 40 40 q0=2.84 7

Continuum damping for Alfvén Cascades (new results) Damping rate grows exponentially as q0 approaches rational surface: Low frequency limit: 8

Frequency and damping rate  - single poloidal harmonic (m=12)  - two coupled poloidal harmonics (m=12, m=11) W G/W Analytic estimate Safety factor q0 Safety factor q0 9

Mysteries in Alfvén Cascades (partially resolved) Transition from Alfvén Cascades to TAE Suppression of Alfvén Cascades at low frequencies 10

Mysteries in Alfvén Cascades (unresolved) Frequency rolling Mode enhancement at low frequency 11

Fishbone onset Linear responses from kinetic and fluid resonances are in balance at the instability threshold but the nonlinear responses can differ significantly. QUESTIONS TO ANSWER: Which resonance produces the dominant nonlinear response? Is this response stabilizing or destabilizing? APPROACH: Analyze nonlinear regime near the instability threshold. Perform hybrid kinetic-MHD simulations to study strong nonlinearity. 12

Linear near-threshold mode Double resonance layer at 13

Early nonlinear dynamics Normalized evolution equations for on-axis displacement with cubic MHD nonlinearity: Explosive nonlinear solution : Weak MHD nonlinearity of the q=1 layer destabilizes fishbone perturbations 14

Remaining challenges Transition from explosive growth to slowly growing MHD structure (island near q=1 surface) Modification of fast particle distribution Explanation of mode saturation and decay Quantitative simulation of frequency sweeping Burst repetition rate in presence of injection 15

Convective transport in phase space . 16

Intermittent losses of fast ions . Experiments show both benign and malignant effects. Rapid losses in early experiments (K. L. Wong, et. al. TFTR; Heidbrink, et. al. DIII-D) Study of rapid loss: IFS- NIFS collaboration, Physics of Plasmas 10, 2888 (2003) 17

Simulation of intermittent losses in TFTR (Y. Todo et al.) TAE excitations reduce stored energy, especially that of counter-injected beam stored beam energy with TAE turbulence 18

Temporal relaxation of radial profile Counter-injected beams are confined only near plasma axis. Co-injected beams are confined efficiently. Pressure gradient periodically collapses at criticality. Large pressure gradient sustained at plasma edge. 19

Resonances in phase space for low amplitude modes . N=1: Red N=2: Green N=3: Blue 20

Resonances in phase space at mode saturation . N=1: Red N=2: Green N=3: Blue 21

Issues in diffusive transport modeling Reconciliation of mode saturation levels with experimental data. Edge effects in fast particle transport. Transport barriers for marginally stable profiles. Resonance overlap in 3D. 22

Theoretical problems to study (please feel free to do more) Diagnostic applications of benign modes. Quantitative interpretation of experimental data for nonlinearly saturated isolated modes (TAE’s, Cascades, high-frequency modes, etc.) Transport barriers for energetic particles in presence of many unstable modes. Parameter window for fast particle confinement in fusion devices. Intermittent strong bursts versus stochastic diffusive transport. Lifecycle of fishbones and EPMs starting from instability threshold. Fast nonlinear frequency sweeping. Interplay of kinetic and fluid resonances. 23

Elements of style Look for puzzles/discrepancies of basic importance. Identify key physics ingredients qualitatively/analytically. Develop internally consistent reduced models and “bare bones” codes to capture and simulate essential physics and to perform broad parameter scan. Develop advanced techniques for large-scale simulations. Use reduced models to validate large codes. Use large codes to model present experiments (quantitatively!) and to extrapolate them (conclusively!) to reactor conditions. 24