2013
Cooper, W A; Chapman, I T; Schmitz, O; Turnbull, A D; Tobias, B J; Lazarus, E A; Turco, F; Lanctot, M J; Evans, T E; Graves, J P; Brunetti, D; Pfefferlé, D; Reimerdes, H; Sauter, O; Halpern, F D; Tran, T M; Coda, S; Duval, B P; B, Labit; Pochelon, A; Turnyanskiy, M R; Lao, L; Luce, T C; Buttery, R; Ferron, J R; Hollmann, E M; Petty, C C; van Zeeland, M; Fenstermacher, M E; Hanson, J M; Lütjens, H
Bifurcated helical core equilibrium states in tokamaks Journal Article
In: Nuclear Fusion, vol. 53, no. 7, pp. 073021, 2013.
Abstract | Links | BibTeX | Tags: helical core, internal kink, MHD equilibrium
@article{cooper-2013,
title = {Bifurcated helical core equilibrium states in tokamaks},
author = {W A Cooper and I T Chapman and O Schmitz and A D Turnbull and B J Tobias and E A Lazarus and F Turco and M J Lanctot and T E Evans and J P Graves and D Brunetti and D Pfefferl\'{e} and H Reimerdes and O Sauter and F D Halpern and T M Tran and S Coda and B P Duval and Labit B and A Pochelon and M R Turnyanskiy and L Lao and T C Luce and R Buttery and J R Ferron and E M Hollmann and C C Petty and M van Zeeland and M E Fenstermacher and J M Hanson and H L\"{u}tjens},
url = {http://stacks.iop.org/0029-5515/53/i=7/a=073021},
doi = {10.1088/0029-5515/53/7/073021},
year = {2013},
date = {2013-06-11},
journal = {Nuclear Fusion},
volume = {53},
number = {7},
pages = {073021},
abstract = {Tokamaks with weak to moderate reversed central shear in which the minimum inverse rotational transform (safety factor) qmin is in the neighbourhood of unity can trigger bifurcated magnetohydrodynamic equilibrium states, one of which is similar to a saturated ideal internal kink mode. Peaked prescribed pressure profiles reproduce the 'snake' structures observed in many tokamaks which has led to a novel explanation of the snake as a bifurcated equilibrium state. Snake equilibrium structures are computed in simulations of the tokamak \`{a} configuration variable (TCV), DIII-D and mega amp spherical torus (MAST) tokamaks. The internal helical deformations only weakly modulate the plasma\textendashvacuum interface which is more sensitive to ripple and resonant magnetic perturbations. On the other hand, the external perturbations do not alter the helical core deformation in a significant manner. The confinement of fast particles in MAST simulations deteriorate with the amplitude of the helical core distortion. These three-dimensional bifurcated solutions constitute a paradigm shift that motivates the applications of tools developed for stellarator research in tokamak physics investigations.},
keywords = {helical core, internal kink, MHD equilibrium},
pubstate = {published},
tppubtype = {article}
}
2012
Pfefferlé, D; Graves, J P; Cooper, W A
Exploitation of a general-coordinate guiding centre code for the redistribution of fast ions in deformed hybrid tokamak equilibria Proceedings Article
In: Journal of Physics: Conference Series, pp. 012020, 2012.
Abstract | Links | BibTeX | Tags: fast particles, helical core, internal kink, MHD equilibrium, VENUS-LEVIS
@inproceedings{pfefferle-first,
title = {Exploitation of a general-coordinate guiding centre code for the redistribution of fast ions in deformed hybrid tokamak equilibria},
author = {D Pfefferl\'{e} and J P Graves and W A Cooper},
url = {http://stacks.iop.org/1742-6596/401/i=1/a=012020},
doi = {10.1088/1742-6596/401/1/012020},
year = {2012},
date = {2012-12-03},
booktitle = {Journal of Physics: Conference Series},
journal = {Journal of Physics: Conference Series},
volume = {401},
number = {1},
pages = {012020},
abstract = {Self-consistent fast ion distributions are usually obtained using a code that solves the guiding-centre equations, with an appropriate fast ion source (e.g. NBI pinis) and sink (e.g. collision operators). Straight field-line coordinate systems, such as Boozer coordinates, are ordinarily convenient due to the simple separation of longitudinal and cross-field motion, and the simple expression of magnetic differential operators. However, these coordinates are found to be near-singular at the boundary of the internal helical region associated with an n = m = 1 infernal mode. These important configurations are associated with many tokamak phenomena, including snakes and long-lived modes [1] in spherical or more conventional devices. Such internal helical states occur when there is a radially extended region where the safety factor is close to unity. Recent calculations predict the possibility of helical equilibria in ITER hybrid scenarios [2]. The ANIMEC code [3] conveniently produces an equilibrium helical state despite choosing for example an axisymmetric fixed boundary. The corresponding magnetic field in these coordinates can now be fed to the newly devised Particle-In-Cell (PIC) code VENUS-LEVIS, which has been upgraded with phase-space Lagrangian guiding-centre orbit equations [4], embodying full 3D anisotropic electromagnetic fields and a formulation that is independent of coordinate choice, despite retaining intrinsic Hamiltonian properties. The simulations are applied to MAST experiments where the presence of a long-lived mode can effect confinement of neutral beam ions, potentially affecting NBI heating and current drive [1]. Neighbouring equilibria from ANIMEC, one helical in the core and the other axisymmetic, permits a precise means of identifying the effect of 3D geometry on the simulated confinement properties of MAST's neutral beam fast ion population. In agreement with the compared experimental data from MAST neutron camera, a significant fraction of particles are pushed out of the helical core region affecting both the measured radial neutron distribution and the heating and current drive properties of the neutral beam population.},
keywords = {fast particles, helical core, internal kink, MHD equilibrium, VENUS-LEVIS},
pubstate = {published},
tppubtype = {inproceedings}
}