Axisymmetric two-fluid plasma equilibria with momentum sources and sinks K G McClements 1 & A Thyagaraja 2 1 EURATOM/CCFE Association, Culham Science Centre,

Slides:

Advertisements

Similar presentations

NSF Site Visit Madison, May 1-2, 2006 Magnetic Helicity Conservation and Transport R. Kulsrud and H. Ji for participants of the Center for Magnetic Self-organization.

Advertisements

Dynamo Effects in Laboratory Plasmas S.C. Prager University of Wisconsin October, 2003.

Self-consistent mean field forces in two-fluid models of turbulent plasmas C. C. Hegna University of Wisconsin Madison, WI Hall Dynamo Get-together PPPL.

Self-consistent mean field forces in two-fluid models of turbulent plasmas C. C. Hegna University of Wisconsin Madison, WI CMSO Meeting Madison, WI August.

Introduction to Plasma-Surface Interactions Lecture 6 Divertors.

Lecture 15: Capillary motion

MHD Concepts and Equations Handout – Walk-through.

Momentum Transport During Reconnection Events in the MST Reversed Field Pinch Alexey Kuritsyn In collaboration with A.F. Almagri, D.L. Brower, W.X. Ding,

Conservation of Linear Momentum.

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

SUGGESTED DIII-D RESEARCH FOCUS ON PEDESTAL/BOUNDARY PHYSICS Bill Stacey Georgia Tech Presented at DIII-D Planning Meeting

Max-Planck- Institut für Plasmaphysik Wendelsteinstraße 1, Greifswald Intrinsic ambipolarity and bootstrap currents in stellarators Per Helander.

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

1 MECH 221 FLUID MECHANICS (Fall 06/07) Tutorial 6 FLUID KINETMATICS.

Forced reconnection studies in the MAST spherical tokamak M P Gryaznevich 1, A Sykes 1, K G McClements 1 T Yamada 2, Y Hayashi 2, R Imazawa 2, Y Ono 2.

Lecture 6 The dielectric response functions. Superposition principle.

Numerical Hydraulics Wolfgang Kinzelbach with Marc Wolf and Cornel Beffa Lecture 1: The equations.

Lecture “Planet Formation” Topic: Introduction to hydrodynamics and magnetohydrodynamics Lecture by: C.P. Dullemond.

Chapter 21 & 22 Electric Charge Coulomb’s Law This force of repulsion or attraction due to the charge properties of objects is called an electrostatic.

F. Cheung, A. Samarian, W. Tsang, B. James School of Physics, University of Sydney, NSW 2006, Australia.

Physics of fusion power Lecture 7: particle motion.

Physics of Fusion power Lecture4 : Quasi-neutrality Force on the plasma.

Conservation Laws for Continua

F.M.H. Cheung School of Physics, University of Sydney, NSW 2006, Australia.

Chapter 5 Diffusion and resistivity

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.

Massively Parallel Magnetohydrodynamics on the Cray XT3 Joshua Breslau and Jin Chen Princeton Plasma Physics Laboratory Cray XT3 Technical Workshop Nashville,

14 th IEA-RFP Workshop, Padova 26 th -28 th April 2010 The SHEq code: an equilibrium calculation tool for SHAx states Emilio Martines, Barbara Momo Consorzio.

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

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.

Plasma Dynamics Lab HIBP E ~ 0 V/m in Locked Discharges Average potential ~ 580 V  ~ V less than in standard rotating plasmas Drop in potential.

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

2 The Neutral Particle Analyzer (NPA) on NSTX Scans Horizontally Over a Wide Range of Tangency Angles Covers Thermal ( keV) and Energetic Ion.

QSH/SHAx states: towards the determination of an helical equilibrium L. Marrelli acknowledging fruitful discussions with S.Cappello, T.Bolzonella, D.Bonfiglio,

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.

SLM 2/29/2000 WAH 13 Mar NBI Driven Neoclassical Effects W. A. Houlberg ORNL K.C. Shaing, J.D. Callen U. Wis-Madison NSTX Meeting 25 March 2002.

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.

1 Importance of two-fluid in helicity injection current drive.

Figure 3: Initial conditions: x=0.4m, y=0m, z=0.37m. v ⊥ =60000m/s. v II varies from 30000m/s, 35000m/s, 40000m/s to 45000m/s (inner to outer). Modelling.

EXTENSIONS OF NEOCLASSICAL ROTATION THEORY & COMPARISON WITH EXPERIMENT W.M. Stacey 1 & C. Bae, Georgia Tech Wayne Solomon, Princeton TTF2013, Santa Rosa,

Modelling the Neoclassical Tearing Mode

Lecture 3. Full statistical description of the system of N particles is given by the many particle distribution function: in the phase space of 6N dimensions.

1 Magnetic components existing in geodesic acoustic modes Deng Zhou Institute of Plasma Physics, Chinese Academy of Sciences.

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

Plasma MHD Activity Observations via Magnetic Diagnostics Magnetic islands, statistical methods, magnetic diagnostics, tokamak operation.

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.

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.

53rd Annual Meeting of the Division of Plasma Physics, November , 2010, Salt Lake City, Utah 5-pin Langmuir probe configured to measure the Reynolds.

53rd Annual Meeting of the Division of Plasma Physics, November , 2011, Salt Lake City, Utah When the total flow will move approximately along the.

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

1 Recent Progress on QPS D. A. Spong, D.J. Strickler, J. F. Lyon, M. J. Cole, B. E. Nelson, A. S. Ware, D. E. Williamson Improved coil design (see recent.

Presented by Yuji NAKAMURA at US-Japan JIFT Workshop “Theory-Based Modeling and Integrated Simulation of Burning Plasmas” and 21COE Workshop “Plasma Theory”

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.

= Boozer g= 2*1e -7 *48*14*5361 =.7205 =0 in net current free stellarator, but not a tokamak. QHS Mirror Predicted Separatrix Position Measurements and.

APS DPP 2006 October Dependence of NTM Stabilization on Location of Current Drive Relative to Island J. Woodby 1 L. Luo 1, E. Schuster 1 F. D.

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

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

Introduction to Plasma Physics and Plasma-based Acceleration

54th Annual Meeting of the Division of Plasma Physics, October 29 – November 2, 2012, Providence, Rhode Island 5-pin Langmuir probe measures floating potential.

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.

Equilibrium and Stability

Chapter 4 Fluid Mechanics Frank White

Huishan Cai, Jintao Cao, Ding Li

Generation of Toroidal Rotation by Gas Puffing

Studies of Bias Induced Plasma Flows in HSX

Influence of energetic ions on neoclassical tearing modes

Part VI:Viscous flows, Re<<1

Presentation transcript:

Axisymmetric two-fluid plasma equilibria with momentum sources and sinks K G McClements 1 & A Thyagaraja 2 1 EURATOM/CCFE Association, Culham Science Centre, Abingdon, Oxfordshire, OX14 3DB, United Kingdom 2 University of Bristol, H. H. Wills Physics Laboratory, Bristol, BS8 1TL, United Kingdom Plasma physics seminar, Australian National University, Canberra, April /19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority

Introduction (1)  Basic tool used to describe axisymmetric plasma equilibria (e.g. tokamaks, accretion discs) is Grad-Shafranov equation 1, obtained from MHD force balance in absence of equilibrium flows & viscosity ( ): (R, ,Z) – right-handed cylindrical coordinates;  (R,Z) - poloidal magnetic flux, defined such that f = f(  ) = RB  - stream function for poloidal current; pressure p = p(  )  Can be generalised to include toroidal rotation – necessary when flow approaches or exceeds local sound speed c s, e.g. in Joint European Torus (JET) 2 or Mega Ampère Spherical Tokamak (MAST) 3 at Culham 2/19 1 Shafranov Sov. Phys.-JETP 6, 545 (1958) 2 de Vries et al. Nucl. Fusion 48, (2008) 3 Akers et al. Proc. 20 th IAEA Fusion Energy Conf., paper EX/4-4 (2005) CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority

Introduction (2)  Flows ~350 km s -1 occurred in MAST during counter-current beam injection 1  driven by j  B torque associated with radial bulk ion current balancing current due to beam ion losses 2  Midplane density profile n e (R) shifted outboard with respect to temperature (assumed to be flux function due to rapid parallel heat transport) 3/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 Akers et al. Proc. 20th IAEA Fusion Energy Conf., paper EX/4-4 (2005) 2 McClements & Thyagaraja Phys. Plasmas 13, (2006) 3 Maschke & Perrin Plasma Phys. 22, 579 (1980)  If flow is purely toroidal, T e & T i are flux functions, flux surfaces rotate as rigid bodies at rate  , & momentum sources/sinks are neglected, then 3

Introduction (3)  Rigid body rotation implied by ideal MHD Ohm’s law + axisymmetry:  - electrostatic potential  What happens when all possible relevant terms in force balance equation(s) are taken into account?  Due to dissipation (in particular neoclassical & turbulent viscosity) flows in tokamaks must be continuously driven  Poloidal flows, when measurable, usually found to be very small (~ few km s -1 ), in accordance with neoclassical predictions, but occasionally observed to be significant fraction of c s, e.g. close to internal transport barriers in JET 1 – such flows could affect equilibrium 2  In this talk I will consider purely toroidal flows 4/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 Crombé et al. PRL 95, (2005) 2 McClements & Hole Phys. Plasmas 17, (2010)

Plasma coordinates (1)  Often convenient to use right-handed plasma-based coordinates ( , ,  ) where toroidal angle  = -  & poloidal angle  is defined such that Jacobian of transformation from laboratory coordinates does not generally vanish in domain of interest: - arc length along flux surface in (R,Z) plane  We set J = J(  ) – generalisation of Hamada coordinates (J = constant) 1 ; facilitates evaluation of flux-surface averages, since volume element is Such coordinate systems are quasi-orthogonal –  ≠ 0 in general  where B  = -B  ; we denote RB  by F = -f 5/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 Hamada Nucl. Fusion 2, 23 (1962)

Plasma coordinates (2)  In steady-state & in absence of poloidal flows, momentum sources & dissipation, F = F(  ) in both ideal MHD 1 & 2-fluid theory (in limit m e → 0) 2  Here we assume only that F is axisymmetric, i.e. F = F(R,Z) or F( ,  )  Ampère’s law  where Hence Axisymmetric ideal MHD with purely toroidal flow & no sources/sinks requires that toroidal component of j  B vanishes  F = F(  ) 6/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 McClements & Thyagaraja Mon. Not. R. Astron. Soc. 323, 733 (2001) 2 Thyagaraja & McClements Phys. Plasmas 13, (2006)

Ion momentum balance  Quasi-neutral plasma with singly-charged ions & electrons, each with scalar pressure; ions have toroidal flow v i = R 2     ion momentum balance equation can be written as For inductive tokamak operation we can write V L – loop voltage (we assume uniform toroidal voltage across plasma);  - resistivity (assumed to be isotropic) 7/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority applied torque momentum loss rate (e.g. due to viscosity) momentum exchange with electrons

Electron momentum balance  In limit m e → 0 electron momentum balance equation (≡ generalised Ohm’s law) can be written as  Momentum conservation   Momentum sources & sinks neglected in electron momentum balance – any momentum acquired by electron via interaction with e.g. beam ions very rapidly transferred to bulk ions, hence for electrons (if this were not the case, beam injection would produce large numbers of highly superthermal electrons, which are not observed)  We neglect external current sources (driven e.g. by beams or radio- frequency waves) & bootstrap current (diamagnetic current associated with drift orbits of trapped particles) 8/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority momentum exchange with ions

Single-fluid momentum balance (1)  Adding ion & electron equations yields where p = p i + p e ; to ensure compatibility with neglect of poloidal flows we consider only toroidal components of, & assume that drag term can be characterised by phenomenological relaxation time   : (for momentum losses arising from neoclassical or turbulent viscosity, more exact expression would involve spatial derivatives of v i )  Substituting our expression for j  B into (1) yields 9/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority (1)

Single-fluid momentum balance (2)  Regarding R 2 & p as functions of  & , & equating components, we obtain  In limit (3) implies F = F(  ) & (2) implies p = p(  ); (1) then reduces to standard form of Grad-Shafranov equation  When   ≠ 0 & F = F(  ) (1) is equivalent to Grad-Shafranov equation for purely toroidal flow obtained by previous authors 1  F = F(  ) to leading order in 10/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority (1) (2) (3) 1 Maschke & Perrin Plasma Phys. 22, 579 (1980)

Variation of density on flux surfaces (1)  Relation between momentum drive & dissipation depends on beam deposition & momentum transport; we consider simple cases to illustrate influence of torque & relaxation time on density distribution  1 st case: F = F(  ) & where K = K(  ); from (2) & (3) on previous slide we obtain m i n   = K &  …  - flux surface average - differs from result for rigidly-rotating flux surfaces when momentum sources & sinks are neglected:  In both cases n increases with R on flux surface – arises from inertial term in ion momentum balance equation, & is qualitatively consistent with measurements in spherical tokamak plasmas with transonic toroidal flows 11/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority

Variation of density on flux surfaces (2)  2 nd case: F & are flux functions → M ≡ m i n   R (toroidal linear momentum per unit volume) is a flux function &  3 rd case: F & are flux functions → L ≡ m i n   R 2 (toroidal angular momentum per unit volume) is a flux function &  In all cases we find that at magnetic axis - agrees well with measurements in National Spherical Torus Experiment (NSTX) at Princeton 1 ; but measurements at magnetic axis alone cannot be used to determine density variation on flux surface 12/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 Menard et al. Nucl. Fusion 43, 330 (2003)

Temperature – density relation: theory  Eliminating n we obtain   =   (T ); e.g. in 1 st case where I, K are flux functions  Expressions for   in terms of T i & T e can be obtained from ion & electron momentum balance equations in limit ; 1 result for rigidly-rotating flux surfaces is   0, T 0,  0 – constants; when T i =T e =T this reduces to → rotation profile predicted to be much flatter than temperature profile 13/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 Thyagaraja & McClements Phys. Plasmas 13, (2006)

Temperature – density relation: experiment  Spectroscopic measurements in JET plasmas with T i  T e show that   & T i have similar profiles, contradicting prediction based on (i) assumption of rigid body rotation & (ii) neglect of momentum sources/sinks  Similar relation between profiles observed in MAST  In order to account for measured rotation & temperature profiles it is necessary to invoke either momentum sources/sinks or non- rigid rotation of flux surfaces 14/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority Rotation, temperature & momentum/ion heat diffusivity profiles in JET #57865; solid black curves show experimental profiles 1 1 Tala et al. Nucl. Fusion 47, 1012 (2007)

Ohm’s law for rotating tokamak plasma When F = F(  ) poloidal component of electron momentum balance yields Flux surface average of this yields Substituting into Grad-Shafranov equation & integrating over (R,Z) → plasma current in terms of loop voltage & resistivity: - could be used e.g. in fluid turbulence codes to calculate loop voltage required to maintain specified current, given profiles of  , , J,  B 2  etc. 15/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority

Radial electric field  Radial component of ion momentum balance equation yields  Last term on right hand side negligible under typical tokamak conditions; averaging remaining terms with respect to  we obtain simple expression for   /  - measure of flux surface-averaged radial electric field; shear of this is thought to play important role in transport barrier physics  Radial electric fields fields can be determined from motional Stark effect measurements; 1 - equilibrium electric field given by above expression could thus be compared directly with experiment 16/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority 1 Rice et al. Nucl. Fusion (1997)

Conclusions 17/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority  Previous analyses of axisymmetric plasma equilibria with toroidal flows extended to take into account continuous drive of such flows when dissipative effects are present (invariably the case in tokamaks)  Ion & electron fluid momentum equations yield three coupled PDEs which indicate that flux surfaces do not rotate rigidly, as frequently assumed & required by ideal MHD in absence of momentum sources/sinks & poloidal flows  For specific assumed relations between momentum drive & damping, expressions can be obtained for variation of density on flux surfaces - in principle can be tested experimentally  Either momentum sources/sinks or non-rigid rotation of flux surfaces must be invoked to account for measured rotation & temperature profiles  Relation derived between loop voltage & plasma current in tokamak plasma with toroidal flow - could be used to determine voltage required to maintain particular current in slowly-evolving discharge  Simple expression obtained for equilibrium radial electric field - can be compared directly with experiment  For further details see McClements & Thyagaraja Plasma Phys. Control. Fusion 53, (2011)

Postscript: ripple transport in MAST (1) 18/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority  MAST has R  0.85m, minor radius a  0.65m, B  0.5T, I p  1MA & is heated by 70keV deuterium neutral beams – plot shows trapped beam ion orbit in (R,Z) plane  Due to presence of N = 12 toroidal field coils at R coil = 2m, toroidal & radial field components are no longer axisymmetric:  even in absence of prompt losses, collisions & turbulence, beam ions are no longer perfectly confined in plasma because

Postscript: ripple transport in MAST (2) 19/19 CCFE is the fusion research arm of the United Kingdom Atomic Energy Authority  Cyclotron resonance between particle motion & ripple field can produce additional transport & loss; 1 resonance condition for zero frequency field perturbation is k II v II =  i where  i is beam ion cyclotron frequency  approximately satisfied by beam ions in MAST  Significant anomalous beam ion transport has been reported in MAST 2 - ripple effects may be contributing to this  Transport of fast ions due to ripple, or other non-axisymmetric perturbations, can be modelled using CUEBIT full orbit test-particle code  Principal aim of my visit is to pursue this project in collaboration with MJH 1 Putvinskii JETP Lett (1982) 2 Turnyanskiy et al. Nucl. Fusion (2009)