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Title: Runaway electrons and magnetic island confinement

Journal Article · · Physics of Plasmas
DOI:https://doi.org/10.1063/1.4960969· OSTI ID:22599889
 [1]
+ Show Author Affiliations
  1. Columbia University, New York, New York 10027 (United States)

The breakup of magnetic surfaces is a central feature of ITER planning for the avoidance of damage due to runaway electrons. Rapid thermal quenches, which lead to large accelerating voltages, are thought to be due to magnetic surface breakup. Impurity injection to avoid and to mitigate both halo and runaway electron currents utilizes massive gas injection or shattered pellets. The actual deposition is away from the plasma center, and the breakup of magnetic surfaces is thought to spread the effects of the impurities across the plasma cross section. The breakup of magnetic surfaces would prevent runaway electrons from reaching relativistic energies were it not for the persistence of non-intercepting flux tubes. These are tubes of magnetic field lines that do not intercept the walls. In simulations and in magnetic field models, non-intercepting flux tubes are found to persist near the magnetic axis and in the cores of magnetic islands even when a large scale magnetic surface breakup occurs. As long as a few magnetic surfaces reform before all of the non-intercepting flux tubes dissipate, energetic electrons confined and accelerated in these flux tubes can serve as the seed electrons for a transfer of the overall plasma current from thermal to relativistic carriers. The acceleration of electrons is particularly strong because of the sudden changes in the poloidal flux that naturally occur in a rapid magnetic relaxation. The physics of magnetic islands as non-intercepting flux tubes is studied. Expressions are derived for (1) the size of islands required to confine energetic runaway electrons, (2) the accelerating electric field in an island, (3) the increase or reduction in the size of an island by the runaway electron current, (4) the approximate magnitude of the runaway current in an island, and (5) the time scale for the evolution of an island.

OSTI ID:
22599889
Journal Information:
Physics of Plasmas, Vol. 23, Issue 8; Other Information: (c) 2016 Author(s); Country of input: International Atomic Energy Agency (IAEA); ISSN 1070-664X
Country of Publication:
United States
Language:
English

Cited By (7)

Simulations of the effects of pre-seeded magnetic islands on the generation of runaway current during disruption on J-TEXT journal June 2019
Kink instabilities of the post-disruption runaway electron beam at low safety factor journal March 2019
Test particles dynamics in the JOREK 3D non-linear MHD code and application to electron transport in a disruption simulation journal December 2017
Electron acceleration in a JET disruption simulation journal August 2018
Observation of toroidal Alfvén eigenmode excited by energetic electrons induced by static magnetic perturbations in the EAST tokamak journal August 2018
Electron acceleration in a JET disruption simulation text January 2018
Test particles dynamics in the JOREK 3D non-linear MHD code and application to electron transport in a disruption simulation text January 2017

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Related Subjects

70 PLASMA PHYSICS AND FUSION TECHNOLOGY
CROSS SECTIONS
ELECTRIC CURRENTS
ELECTRIC FIELDS
ELECTRIC POTENTIAL
GAS INJECTION
ITER TOKAMAK
MAGNETIC FIELDS
MAGNETIC ISLANDS
MAGNETIC SURFACES
PLANNING
PLASMA
RELATIVISTIC RANGE
RUNAWAY ELECTRONS
SIMULATION
TAIL ELECTRONS
TUBES
WALLS