Your search keyword '"Ian Abel"' showing total 14 results

1. Multiscale Modelling for Tokamak Pedestals

Author

Axel Hallenbert and Ian Abel

Subjects

Physics, Tokamak, Gyroradius, Turbulence, Physics::Instrumentation and Detectors, FOS: Physical sciences, Mechanics, Condensed Matter Physics, System of linear equations, 01 natural sciences, Physics - Plasma Physics, 010305 fluids & plasmas, law.invention, Plasma Physics (physics.plasm-ph), Pedestal, law, Physics::Plasma Physics, Beta (plasma physics), 0103 physical sciences, Gyrokinetics, 010306 general physics, Asymptotic expansion

Abstract

Pedestal modelling is crucial to predict the performance of future fusion devices. Current modelling efforts suffer either from a lack of kinetic physics, or an excess of computational complexity. To ameliorate these problems, we take a first-principles multiscale approach to the pedestal. We will present three separate sets of equations, covering the dynamics of Edge Lo- calised Modes, the inter-ELM pedestal, and pedestal turbulence, respectively. Precisely how these equations should be coupled to each other are covered in detail. This framework is completely self-consistent; it is derived from first principles by means an asymptotic expansion in appropriate small parameters. The derivation exploits the narrowness of the pedestal region, the smallness of the thermal gyroradius, and the low plasma $\beta$ typical of current pedestal operation to achieve its simplifications. The relationship between this framework and gyrokinetics is analysed, and possibilities to directly match this framework onto multiscale gyrokinetics are explored. A detailed comparison between our model and other models in the literature is performed. Finally, the potential for matching this framework onto an open-field-line region is discussed., Comment: 49 pages; Accepted for publication in the Journal of Plasma Physics

Published

2017

2. Astrophysical gyrokinetics: Turbulence in pressure-anisotropic plasmas at ion scales and beyond

Author

Matthew W. Kunz, Alexander Schekochihin, Katja Klein, and Ian Abel

Subjects

Physics, High Energy Astrophysical Phenomena (astro-ph.HE), Conservation law, 010504 meteorology & atmospheric sciences, Turbulence, FOS: Physical sciences, Dissipation, Condensed Matter Physics, 01 natural sciences, Physics - Plasma Physics, Space Physics (physics.space-ph), Computational physics, Plasma Physics (physics.plasm-ph), Wavelength, Distribution function, Physics - Space Physics, Physics::Plasma Physics, 0103 physical sciences, Gyrokinetics, Physics::Space Physics, Magnetohydrodynamics, Anisotropy, Astrophysics - High Energy Astrophysical Phenomena, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

We present a theoretical framework for describing electromagnetic kinetic turbulence in a multi-species, magnetized, pressure-anisotropic plasma. Turbulent fluctuations are assumed to be small compared to the mean field, to be spatially anisotropic with respect to it, and to have frequencies small compared to the ion cyclotron frequency. At scales above the ion Larmor radius, the theory reduces to the pressure-anisotropic generalization of kinetic reduced magnetohydrodynamics (KRMHD) formulated by Kunz et al. (2015). At scales at and below the ion Larmor radius, three main objectives are achieved. First, we analyse the linear response of the pressure-anisotropic gyrokinetic system, and show it to be a generalisation of previously explored limits. The effects of pressure anisotropy on the stability and collisionless damping of Alfvenic and compressive fluctuations are highlighted, with attention paid to the spectral location and width of the frequency jump that occurs as Alfven waves transition into kinetic Alfven waves. Secondly, we derive and discuss a general free-energy conservation law, which captures both the KRMHD free-energy conservation at long wavelengths and dual cascades of kinetic Alfven waves and ion entropy at sub-ion-Larmor scales. We show that non-Maxwellian features in the distribution function change the amount of phase mixing and the efficiency of magnetic stresses, and thus influence the partitioning of free energy amongst the cascade channels. Thirdly, a simple model is used to show that pressure anisotropy can cause large variations in the ion-to-electron heating ratio due to the dissipation of Alfvenic turbulence. Our theory provides a foundation for determining how pressure anisotropy affects the turbulent fluctuation spectra, the differential heating of particle species, and the ratio of parallel and perpendicular phase mixing in space and astrophysical plasmas., Comment: 59 pages, 6 figures, accepted for publication in Journal of Plasma Physics (original 28 Nov 2017); abstract abridged

Published

2017

3. Resonant Excitation of Shear Alfvén Perturbations by Trapped Energetic Ions in a Tokamak

Author

Ian Abel, S. E. Sharapov, Jet-Efda Contributors, and Boris Breizman

Subjects

Physics, Fusion, Tokamak, Analytical expressions, Joint European Torus, Condensed Matter Physics, Physics - Plasma Physics, law.invention, Ion, Shear (geology), law, Cascade, Quantum electrodynamics, Excitation

Abstract

A new analytic expression is derived for the resonant drive of high n Alfvenic modes by particles accelerated to high energy by Ion Cyclotron Resonance Heating. This derivation includes finite orbit effects, and the formalism is completely non-perturbative. The high-n limit is used to calculate the complex particle response integrals along the orbits explicitly. This new theory is applied to downward sweeping Alfven Cascade quasimodes completing the theory of these modes, and making testable predictions. These predictions are found to be consistent with experiments carried out on the Joint European Torus [P. H. Rebut and B. E. Keen, Fusion Technol. 11, 13 (1987)]., Comment: 31 pages, 6 figures

Published

2016

4. Linearized model Fokker-Planck collision operators for gyrokinetic simulations. I. Theory

Author

William Dorland, Alexander Schekochihin, Steven Cowley, Michael Barnes, and Ian Abel

Subjects

Physics, Scattering, Turbulence, FOS: Physical sciences, Computational Physics (physics.comp-ph), Condensed Matter Physics, Collision, Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), symbols.namesake, Operator (computer programming), Classical mechanics, Phase space, Boltzmann constant, symbols, Fokker–Planck equation, Entropy (energy dispersal), Nuclear Experiment, Physics - Computational Physics

Abstract

A new analytically and numerically manageable model collision operator is developed specifically for turbulence simulations. The like-particle collision operator includes both pitch-angle scattering and energy diffusion and satisfies the physical constraints required for collision operators: it conserves particles, momentum and energy, obeys Boltzmann's H-theorem (collisions cannot decrease entropy), vanishes on a Maxwellian, and efficiently dissipates small-scale structure in the velocity space. The process of transforming this collision operator into the gyroaveraged form for use in gyrokinetic simulations is detailed. The gyroaveraged model operator is shown to have more suitable behavior at small scales in phase space than previously suggested models. A model operator for electron-ion collisions is also presented., Comment: revtex, 12 pages

Published

2016

5. First principles of modelling the stabilization of microturbulence by fast ions

Author

Ian Abel, Alexander Lukin, Stefan Matejcik, Soare Sorin, Francesco Romanelli, Bohdan Bieg, George Wilkie, Vladislav Plyusnin, José Vicente, Alberto Loarte, Bor Kos, Axel Jardin, Rajnikant Makwana, CHIARA MARCHETTO, Marco Wischmeier, William Tang, Choong-Seock Chang, Manuel Garcia-munoz, Universidad de Sevilla. Departamento de Física Atómica, Molecular y Nuclear, Universidad de Sevilla. RNM138: Física Nuclear Aplicada, Department of Physics, and Materials Physics

Subjects

Nuclear and High Energy Physics, Work (thermodynamics), Tokamak, Other Physics Topics, Gyrokinetics, education, FOS: Physical sciences, 114 Physical sciences, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Ion, law.invention, Physics::Plasma Physics, law, 0103 physical sciences, Microturbulence, 010306 general physics, Physics, Applied Mechanics, Turbulence, Fast ions, Mechanics, Condensed Matter Physics, Fusion, Plasma and Space Physics, Physics - Plasma Physics, Stabilization, Plasma Physics (physics.plasm-ph), Nonlinear system, Phenomenology (particle physics), Simulation

Abstract

The observation that fast ions stabilize ion-temperature-gradient-driven microturbulence has profound implications for future fusion reactors. It is also important in optimizing the performance of present-day devices. In this work, we examine in detail the phenomenology of fast ion stabilization and present a reduced model which describes this effect. This model is derived from the high-energy limit of the gyrokinetic equation and extends the existing "dilution" model to account for nontrivial fast ion kinetics. Our model provides a physically-transparent explanation for the observed stabilization and makes several key qualitative predictions. Firstly, that different classes of fast ions, depending on their radial density or temperature variation, have different stabilizing properties. Secondly, that zonal flows are an important ingredient in this effect precisely because the fast ion zonal response is negligible. Finally, that in the limit of highly-energetic fast ions, their response approaches that of the "dilution" model; in particular, alpha particles are expected to have little, if any, stabilizing effect on plasma turbulence. We support these conclusions through detailed linear and nonlinear gyrokinetic simulations., Comment: 29 pages, 10 figures, 3 tables

Published

2018

6. Transport and deceleration of fusion products in microturbulence

Author

Ian Abel, George Wilkie, Matt Landreman, and William Dorland

Subjects

Physics, Fusion, Energy distribution, Turbulence, FOS: Physical sciences, Inversion (meteorology), Alpha particle, Condensed Matter Physics, 01 natural sciences, Physics - Plasma Physics, 010305 fluids & plasmas, Computational physics, Plasma Physics (physics.plasm-ph), Impurity, 0103 physical sciences, A priori and a posteriori, Microturbulence, 010306 general physics

Abstract

The velocity-space distribution of alpha particles born in fusion devices is subject to modification at moderate energies due to turbulent transport. Therefore, one must calculate the evolution of an equilibrium distribution whose functional form is not known \emph{a priori}. Using a novel technique, applicable to any trace impurity, we have made this calculation not only possible, but particularly efficient. We demonstrate a microturbulence-induced departure from the local slowing-down distribution, an inversion of the energy distribution, and associated modifications to the alpha heating and pressure profiles in an ITER-like scenario., Comment: 5 pages, 4 figures

Published

2016

7. Inertial-Range Kinetic Turbulence in Pressure-Anisotropic Astrophysical Plasmas

Author

Steven Cowley, Ian Abel, Alexander Schekochihin, Christopher H. K. Chen, and Matthew W. Kunz

Subjects

Physics, High Energy Astrophysical Phenomena (astro-ph.HE), Turbulence, FOS: Physical sciences, Plasma, Mechanics, Condensed Matter Physics, Instability, Space Physics (physics.space-ph), Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), Solar wind, Distribution function, Physics - Space Physics, Cascade, Physics::Plasma Physics, Gyrokinetics, Physics::Space Physics, Magnetohydrodynamics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

A theoretical framework for low-frequency electromagnetic (drift-)kinetic turbulence in a collisionless, multi-species plasma is presented. The result generalises reduced magnetohydrodynamics (RMHD) and kinetic RMHD (Schekochihin et al. 2009) for pressure-anisotropic plasmas, allowing for species drifts---a situation routinely encountered in the solar wind and presumably ubiquitous in hot dilute astrophysical plasmas (e.g. intracluster medium). Two main objectives are achieved. First, in a non-Maxwellian plasma, the relationships between fluctuating fields (e.g., the Alfven ratio) are order-unity modified compared to the more commonly considered Maxwellian case, and so a quantitative theory is developed to support quantitative measurements now possible in the solar wind. The main physical feature of low-frequency plasma turbulence survives the generalisation to non-Maxwellian distributions: Alfvenic and compressive fluctuations are energetically decoupled, with the latter passively advected by the former; the Alfvenic cascade is fluid, satisfying RMHD equations (with the Alfven speed modified by pressure anisotropy and species drifts), whereas the compressive cascade is kinetic and subject to collisionless damping. Secondly, the organising principle of this turbulence is elucidated in the form of a generalised kinetic free-energy invariant. It is shown that non-Maxwellian features in the distribution function reduce the rate of phase mixing and the efficacy of magnetic stresses; these changes influence the partitioning of free energy amongst the various cascade channels. As the firehose or mirror instability thresholds are approached, the dynamics of the plasma are modified so as to reduce the energetic cost of bending magnetic-field lines or of compressing/rarefying them. Finally, it is shown that this theory can be derived as a long-wavelength limit of non-Maxwellian slab gyrokinetics., 61 pages, accepted to Journal of Plasma Physics; Abstract abridged

Published

2015

8. Validating modelling assumptions of alpha particles in electrostatic turbulence

Author

William Dorland, Edmund Highcock, George Wilkie, and Ian Abel

Subjects

Physics, Work (thermodynamics), Tokamak, Turbulence, Linear system, Flux, FOS: Physical sciences, Alpha particle, Condensed Matter Physics, Physics - Plasma Physics, law.invention, Computational physics, Ion, Plasma Physics (physics.plasm-ph), Distribution (mathematics), law, Physics::Plasma Physics

Abstract

To rigorously model fast ions in fusion plasmas, a non-Maxwellian equilibrium distribution must be used. In the work, the response of high-energy alpha particles to electrostatic turbulence has been analyzed for several different tokamak parameters. Our results are consistent with known scalings and experimental evidence that alpha particles are generally well-confined: on the order of several seconds. It is also confirmed that the effect of alphas on the turbulence is negligible at realistically low concentrations, consistent with linear theory. It is demonstrated that the usual practice of using a high-temperature Maxwellian gives incorrect estimates for the radial alpha particle flux, and a method of correcting it is provided. Furthermore, we see that the timescales associated with collisions and transport compete at moderate energies, calling into question the assumption that alpha particles remain confined to a flux surface that is used in the derivation of the slowing-down distribution., Comment: 23 pages, 13 figures, submitted to the Journal of Plasma Physics

Published

2014

9. Experimental signatures of critically balanced turbulence in MAST

Author

A. R. Field, Ian Abel, Greg Colyer, Young-chul Ghim, Alexander Schekochihin, Michael Barnes, S. Zoletnik, D. Dunai, Felix I. Parra, and Steven Cowley

Subjects

Physics, Turbulence, General Physics and Astronomy, Plasma, Magnetohydrodynamic turbulence, Physics - Plasma Physics, Ion, Magnetic field, Classical mechanics, Amplitude, Physics::Plasma Physics, High Energy Physics::Experiment, Emission spectrum, Atomic physics, Anisotropy

Abstract

Beam Emission Spectroscopy (BES) measurements of ion-scale density fluctuations in the MAST tokamak are used to show that the turbulence correlation time, the drift time associated with ion temperature or density gradients, the particle (ion) streaming time along the magnetic field and the magnetic drift time are consistently comparable, suggesting a "critically balanced" turbulence determined by the local equilibrium. The resulting scalings of the poloidal and radial correlation lengths are derived and tested. The nonlinear time inferred from the density fluctuations is longer than the other times; its ratio to the correlation time scales as $\nu_{*i}^{-0.8\pm0.1}$, where $\nu_{*i}=$ ion collision rate/streaming rate. This is consistent with turbulent decorrelation being controlled by a zonal component, invisible to the BES, with an amplitude exceeding the drift waves' by $\sim \nu_{*i}^{-0.8}$., Comment: 6 pages, 4 figures, submitted to PRL

Published

2013

10. Global anomalous transport of ICRH- and NBI-heated fast ions

Author

Ian Abel, William Dorland, George Wilkie, Tünde Fülöp, and Istvan Pusztai

Subjects

Physics, Turbulence, Cyclotron resonance, FOS: Physical sciences, Radius, Condensed Matter Physics, 01 natural sciences, Physics - Plasma Physics, 010305 fluids & plasmas, Ion, Computational physics, Plasma Physics (physics.plasm-ph), Nuclear Energy and Engineering, Physics::Plasma Physics, 0103 physical sciences, Gyrokinetics, Pinch, Microturbulence, 010306 general physics, Ion cyclotron resonance

Abstract

By taking advantage of the trace approximation, one can gain an enormous computational advantage when solving for the global turbulent transport of impurities. In particular, this makes feasible the study of non-Maxwellian transport coupled in radius and energy, allowing collisions and transport to be accounted for on similar time scales, as occurs for fast ions. In this work, we study the fully-nonlinear ITG-driven trace turbulent transport of locally heated and injected fast ions. Previous results indicated the existence of MeV-range minorities heated by cyclotron resonance, and an associated density pinch effect. Here, we build upon this result using the t3core code to solve for the distribution of these minorities, consistently including the effects of collisions, gyrokinetic turbulence, and heating. Using the same tool to study the transport of injected fast ions, we contrast the qualitative features of their transport with that of the heated minorities. Our results indicate that heated minorities are more strongly affected by microturbulence than injected fast ions. The physical interpretation of this difference provides a possible explanation for the observed synergy when NBI heating is combined with ICRH. Furthermore, we move beyond the trace approximation to develop a model which allows one to easily account for the reduction of anomalous transport due to the presence of fast ions in electrostatic turbulence., 13 pages, 6 figures

Published

2017

11. Multiscale gyrokinetics for rotating tokamak plasmas: fluctuations, transport and energy flows

Author

Steven Cowley, Ian Abel, Michael Barnes, Alexander Schekochihin, E. Wang, Gabriel G. Plunk, and William Dorland

Subjects

Physics, Conservation law, Tokamak, Turbulence, Gyroradius, FOS: Physical sciences, General Physics and Astronomy, Plasma, Mechanics, Physics - Plasma Physics, law.invention, Plasma Physics (physics.plasm-ph), Distribution function, Physics::Plasma Physics, law, Physics::Space Physics, Gyrokinetics, Asymptotic expansion

Abstract

This paper presents a complete theoretical framework for plasma turbulence and transport in tokamak plasmas. The fundamental scale separations present in plasma turbulence are codified as an asymptotic expansion in the ratio of the gyroradius to the equilibrium scale length. Proceeding order-by-order in this expansion, a framework for plasma turbulence is developed. It comprises an instantaneous equilibrium, the fluctuations driven by gradients in the equilibrium quantities, and the transport-timescale evolution of mean profiles of these quantities driven by the fluctuations. The equilibrium distribution functions are local Maxwellians with each flux surface rotating toroidally as a rigid body. The magnetic equillibrium is obtained from the Grad-Shafranov equation for a rotating plasma and the slow (resistive) evolution of the magnetic field is given by an evolution equation for the safety factor q. Large-scale deviations of the distribution function from a Maxwellian are given by neoclassical theory. The fluctuations are determined by the high-flow gyrokinetic equation, from which we derive the governing principle for gyrokinetic turbulence in tokamaks: the conservation and local cascade of free energy. Transport equations for the evolution of the mean density, temperature and flow velocity profiles are derived. These transport equations show how the neoclassical corrections and the fluctuations act back upon the mean profiles through fluxes and heating. The energy and entropy conservation laws for the mean profiles are derived. Total energy is conserved and there is no net turbulent heating. Entropy is produced by the action of fluxes flattening gradients, Ohmic heating, and the equilibration of mean temperatures. Finally, this framework is condensed, in the low-Mach-number limit, to a concise set of equations suitable for numerical implementation., Comment: 113 pages, 3 figures

Published

2013

12. Overview of physics results from MAST towards ITER/DEMO and the MAST Upgrade

Author

Erwin Verwichte, K. Imada, R. Zagórski, J. R. Robinson, A. Kirk, M. Kocan, M. Romanelli, I. T. Chapman, Simon Freethy, G. Fishpool, Ian Abel, E. Havlickova, N. J. Conway, S. Zoletnik, V. A. Rozhansky, Young-chul Ghim, D. F. Howell, Michael Barnes, S. Saarelma, M. Cox, A. W. Morris, K. J. Gibson, G. McArdle, R. Scannell, A. Sykes, Daniel Dunai, E. G. Kaveeva, Bogdan Hnat, M. Price, B. Lloyd, R. J. Akers, Felix I. Parra, Alexander Schekochihin, P. Denner, C. D. Challis, D Temple, T. C. Hender, L. Garzotti, O. M. Jones, A. Allan, M. D. Driscoll, P. Cahyna, A. Darke, N. C. Hawkes, S. Sangaroon, H. R. Wilson, Steven Cowley, Romualdo Martín, S. Elmore, J. Horacek, Michael Lehnen, G. Naylor, Edmund Highcock, R. G. L. Vann, Y. Dnestrovsky, N. Ben Ayed, R. O. Dendy, A. V. Danilov, Wojciech Fundamenski, H. Leggate, P. Molchanov, K. G. McClements, T. O'Gorman, I. Wodniak, P. Voskoboynikov, A. N. Saveliev, J. Seidl, David Taylor, S. E. Sharapov, N. C. Barratt, H. F. Meyer, G. P. Maddison, D. Higgins, Greg Colyer, S. Warder, A. Patel, M. Turnyanskiy, D. Ciric, Eric Nardon, A.J. Thornton, C. M. Roach, J. R. Harrison, Ben F. McMillan, S. Lisgo, Vladimir Shevchenko, G. De Temmerman, Mikhail Gryaznevich, Patrick Tamain, L. Appel, Volker Naulin, Benjamin Daniel Dudson, Otto Asunta, S. Shibaev, P. Dura, D. Stork, Clive Michael, M. De Bock, A. Y. Dnestrovsky, Greg J. Tallents, John Canik, Saskia Mordijck, Yunfeng Liang, Fulvio Militello, G. Cunningham, Yueqiang Liu, Anders Nielsen, G.M. Voss, Thomas Morgan, Matthew Lilley, S. D. Pinches, J. Storrs, J. Mailloux, D. L. Keeling, Matthew Hole, B. J. Crowley, M. Valovic, Marco Cecconello, P. Hill, R. J. Lake, A. R. Field, N. Thomas-Davies, D. Muir, S. Allan, Stanislas Pamela, David Dickinson, James W. Bradley, M. R. Dunstan, William Heidbrink, M.R. O'Brien, MAST Team, NBI Team, and Science and Technology of Nuclear Fusion

Subjects

Physics, Nuclear and High Energy Physics, Mega Ampere Spherical Tokamak, Heat flux, Physics::Plasma Physics, Turbulence, Divertor, Magnetic confinement fusion, Spherical tokamak, Condensed Matter Physics, Neutral beam injection, Resonant magnetic perturbations, Computational physics

Abstract

New diagnostic, modelling and plant capability on the Mega Ampère Spherical Tokamak (MAST) have delivered important results in key areas for ITER/DEMO and the upcoming MAST Upgrade, a step towards future ST devices on the path to fusion currently under procurement. Micro-stability analysis of the pedestal highlights the potential roles of micro-tearing modes and kinetic ballooning modes for the pedestal formation. Mitigation of edge localized modes (ELM) using resonant magnetic perturbation has been demonstrated for toroidal mode numbers n = 3, 4, 6 with an ELM frequency increase by up to a factor of 9, compatible with pellet fuelling. The peak heat flux of mitigated and natural ELMs follows the same linear trend with ELM energy loss and the first ELM-resolved Ti measurements in the divertor region are shown. Measurements of flow shear and turbulence dynamics during L-H transitions show filaments erupting from the plasma edge whilst the full flow shear is still present. Off-axis neutral beam injection helps to strongly reduce the redistribution of fast-ions due to fishbone modes when compared to on-axis injection. Low-k ion-scale turbulence has been measured in L-mode and compared to global gyro-kinetic simulations. A statistical analysis of principal turbulence time scales shows them to be of comparable magnitude and reasonably correlated with turbulence decorrelation time. Te inside the island of a neoclassical tearing mode allow the analysis of the island evolution without assuming specific models for the heat flux. Other results include the discrepancy of the current profile evolution during the current ramp-up with solutions of the poloidal field diffusion equation, studies of the anomalous Doppler resonance compressional Alfvén eigenmodes, disruption mitigation studies and modelling of the new divertor design for MAST Upgrade. The novel 3D electron Bernstein synthetic imaging shows promising first data sensitive to the edge current profile and flows. © 2013 IAEA, Vienna.

Published

2013

13. Direct multiscale coupling of a transport code to gyrokinetic turbulence codes

Author

Ian Abel, T. Goerler, Michael Barnes, Frank Jenko, William Dorland, and Greg Hammett

Subjects

Physics, Coupling, Jet (fluid), Turbulence, FOS: Physical sciences, Solver, Condensed Matter Physics, Grid, Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), Nonlinear system, Orders of magnitude (time), Physics::Plasma Physics, Direct coupling, Statistical physics

Abstract

Direct coupling between a transport solver and local, nonlinear gyrokinetic calculations using the multiscale gyrokinetic code TRINITY [M. Barnes, Ph.D. thesis, arxiv:0901.2868] is described. The coupling of the microscopic and macroscopic physics is done within the framework of multiscale gyrokinetic theory, of which we present the assumptions and key results. An assumption of scale separation in space and time allows for the simulation of turbulence in small regions of the space-time grid, which are embedded in a coarse grid on which the transport equations are implicitly evolved. This leads to a reduction in computational expense of several orders of magnitude, making first-principles simulations of the full fusion device volume over the confinement time feasible on current computing resources. Numerical results from TRINITY simulations are presented and compared with experimental data from JET and ASDEX Upgrade plasmas., 12 pages, 13 figures, invited paper for 2009 APS-DPP meeting, submitted to Phys. Plasmas

Published

2010

14. Gyrokinetic simulations of spherical tokamaks

Author

Nuno Loureiro, David Dickinson, M. Valovic, R. J. Hastie, Alexander Schekochihin, M. Reshko, Wayne Arter, Edmund Highcock, Yann Camenen, William Dorland, Steven Cowley, Gregory W. Hammett, Ian Abel, H. R. Wilson, S. Saarelma, J. W. Connor, R.J. Akers, F. J. Casson, Michael Barnes, W. Guttenfelder, Greg Colyer, C. M. Roach, A. G. Peeters, and A. R. Field

Subjects

Physics, Tokamak, Toroid, Turbulence, K-epsilon turbulence model, Electron, Mechanics, Condensed Matter Physics, Kinetic energy, law.invention, Physics::Fluid Dynamics, Classical mechanics, Nuclear Energy and Engineering, Shear (geology), Physics::Plasma Physics, law, Electron temperature

Abstract

This paper reviews transport and confinement in spherical tokamaks (STs) and our current physics understanding of this that is partly based on gyrokinetic simulations. Equilibrium flow shear plays an important role, and we show how this is consistently included in the gyrokinetic framework for flows that greatly exceed the diamagnetic velocity. The key geometry factors that influence the effectiveness of turbulence suppression by flow shear are discussed, and we show that toroidal equilibrium flow shear can sometimes entirely suppress ion scale turbulence in today's STs. Advanced nonlinear simulations of electron temperature gradient (ETG) driven turbulence, including kinetic ion physics, collisions and equilibrium flow shear, support the model that ETG turbulence can explain electron heat transport in many ST discharges. © 2009 IOP Publishing Ltd.

Published

2009