A Novel Pseudo-Spectral Time-Domain Theory of Magnetic Neutron Scattering Illustrated Using A Uniformly Magnetized Sphere
Abstract
A universal numerical method is developed for the investigation of magnetic neutron scattering. By applying the pseudospectral-time-domain (PSTD) algorithm to the spinor version of the Schr\"odinger equation, the evolution of the spin-state of the scattered wave can be solved in full space and time. This extra spin degree of freedom brings some unique new features absent in the numerical theory on the scalar wave scatterings [1]. Different numerical stability condition has to be re-derived due to the coupling between the different spin states. As the simplest application, the neutron scattering by the magnetic field of a uniformly magnetized sphere is studied. The PSTD predictions are compared with those from the Born-approximation. This work not only provides a systematic tool for analyzing spin-matter interactions, but also builds the forward model for testing novel neutron imaging methodologies, such as the newly developed thermal neutron Fourier-transform ghost imaging.
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