Open AccessThe Hamiltonian Structure and Euler-Poincare Formulation of the Valsov-Maxwell and Gyrokinetic System
Author(s) -
Hanna Squire
Publication year - 2012
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/1057031
Subject(s) - poisson bracket , hamiltonian (control theory) , maxwell's equations , mathematical physics , noether's theorem , lie algebra , mathematics , legendre transformation , lie group , euler's formula , semidirect product , symplectic integrator , jacobi identity , hamiltonian mechanics , symplectic geometry , classical mechanics , physics , phase space , mathematical analysis , quantum mechanics , lagrangian , pure mathematics , moment map , group (periodic table) , mathematical optimization
We present a new variational principle for the gyrokinetic system, similar to the Maxwell-Vlasov action presented in Ref. 1. The variational principle is in the Eulerian frame and based on constrained variations of the phase space fluid velocity and particle distribution function. Using a Legendre transform, we explicitly derive the field theoretic Hamiltonian structure of the system. This is carried out with the Dirac theory of constraints, which is used to construct meaningful brackets from those obtained directly from Euler-Poincare theory. Possible applications of these formulations include continuum geometric integration techniques, large-eddy simulation models and Casimir type stability methods.
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