Parallel heat transport in integrable and chaotic magnetic fields

The study of transport in magnetized plasmas is a problem of fundamental interest in controlled fusion, space plasmas, and astrophysics research. Three issues make this problem particularly challenging: (i) The extreme anisotropy between the parallel (i.e., along the magnetic field), χ || , and the...

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Bibliographic Details
Published in:Physics of plasmas 2012-05, Vol.19 (5), p.056112-056112-13
Main Authors: del-Castillo-Negrete, D., Chacón, L.
Format: Article
Language:English
Subjects:
ALGORITHMS
ANISOTROPY
ASTROPHYSICS
CASTING
CLOSURES
CONSTRUCTION
DIFFUSION
GEOMETRY
ISLANDS
LAGRANGIAN FUNCTION
MAGNETIC FIELD CONFIGURATIONS
MAGNETIC FIELDS
MATERIALS SCIENCE
NUMERICAL SOLUTION
POLLUTION
TRANSPORT
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Summary:The study of transport in magnetized plasmas is a problem of fundamental interest in controlled fusion, space plasmas, and astrophysics research. Three issues make this problem particularly challenging: (i) The extreme anisotropy between the parallel (i.e., along the magnetic field), χ || , and the perpendicular, χ ⊥ , conductivities ( χ || / χ ⊥ may exceed 10 10 in fusion plasmas); (ii) Nonlocal parallel transport in the limit of small collisionality; and (iii) Magnetic field lines chaos which in general complicates (and may preclude) the construction of magnetic field line coordinates. Motivated by these issues, we present a Lagrangian Green's function method to solve the local and non-local parallel transport equation applicable to integrable and chaotic magnetic fields in arbitrary geometry. The method avoids by construction the numerical pollution issues of grid-based algorithms. The potential of the approach is demonstrated with nontrivial applications to integrable (magnetic island), weakly chaotic (Devil's staircase), and fully chaotic magnetic field configurations. For the latter, numerical solutions of the parallel heat transport equation show that the effective radial transport, with local and non-local parallel closures, is non-diffusive, thus casting doubts on the applicability of quasilinear diffusion descriptions. General conditions for the existence of non-diffusive, multivalued flux-gradient relations in the temperature evolution are derived.
ISSN:1070-664X
1089-7674
DOI:10.1063/1.3696054