Hamiltonian theory of guiding-centre motion in an electric field with strong gradient

Michel Dirickx, B. Weyssow

Research output: Contribution to journalArticlepeer-review

Abstract

The guiding-centre equations of motion of a classical charged particle in a strong magnetic field and a strongly sheared electric field are derived. They can be used to analyse the dynamics of particles in electromagnetic fields whose spatial profiles are similar to those observed during the H mode in the DIII-D tokamak, for instance. The derivation of the equations of motion is performed up to second order in the drift parameter by applying a Hamiltonian pseudocanonical transformation that removes the gyrophase induced by the magnetic field. The main difference with the standard case of a slowly varying electric field relates to the variation of the new gyrophase and to the expression for the magnetic moment : mv2/2B must be replaced by (mv2/2B) [1 + (e/2mΩ2) ∇·E]. The latter case is also reconsidered - mainly to reveal the consequences of the removal of a hidden divergence for small parallel velocities resulting from the usual averaging transformation.

Original languageEnglish
Pages (from-to)211-242
Number of pages32
JournalJournal of Plasma Physics
Volume59
Issue number2
DOIs
Publication statusPublished - 1998

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