Alfven Wave Mode Conversion in Neutron Star Magnetospheres: A Semi-analytic Approach
Alexander Y. Chen, Yajie Yuan, Dominic Bernardi
arXiv:2404.06431v1 Announce Type: new
Abstract: We write down the force-free electrodynamics (FFE) equations in dipole coordinates, and solve for normal modes corresponding to Alfv’enic perturbations in the magnetosphere of a neutron star. We show that a single Alfv’en wave propagating on dipole field lines spontaneously sources a fast magnetosonic (fms) wave at the next order in the perturbation expansion, without needing 3-wave interaction. The frequency of the sourced fms wave is twice the original Alfv’en wave frequency, and the wave propagates spherically outwards. The properties of the outgoing fms wave can be computed exactly using the usual devices of classical electrodynamics. We extend the calculation to the closed zone of a rotating neutron star magnetosphere, and show that the Alfv’en wave also sources a spherical fms wave but at the same frequency as the primary Alfv’en wave.arXiv:2404.06431v1 Announce Type: new
Abstract: We write down the force-free electrodynamics (FFE) equations in dipole coordinates, and solve for normal modes corresponding to Alfv’enic perturbations in the magnetosphere of a neutron star. We show that a single Alfv’en wave propagating on dipole field lines spontaneously sources a fast magnetosonic (fms) wave at the next order in the perturbation expansion, without needing 3-wave interaction. The frequency of the sourced fms wave is twice the original Alfv’en wave frequency, and the wave propagates spherically outwards. The properties of the outgoing fms wave can be computed exactly using the usual devices of classical electrodynamics. We extend the calculation to the closed zone of a rotating neutron star magnetosphere, and show that the Alfv’en wave also sources a spherical fms wave but at the same frequency as the primary Alfv’en wave.