Action-angle coordinates for motion in a straight magnetic field with constant gradient

Abstract

The motion of a charged particle in a straight magnetic field B = B(y)\, z with a constant perpendicular gradient is solved exactly in terms of elliptic functions and integrals. The motion can be decomposed in terms of a periodic motion along the y-axis and a drift motion along the x-axis. The periodic motion can be described as a particle trapped in a symmetric quartic potential in y. The canonical transformation from the canonical coordinates (y,Py) to the action-angle coordinates (J,θ) is solved explicitly in terms of a generating function S(θ,J) that is expressed in terms of Jacobi elliptic functions. The presence of a weak constant electric field E = E0\, y introduces an asymmetric component to the quartic potential, and the associated periodic motion is solved perturbatively up to second order.