Title :
Hybrid FE-FFTM Algorithm for Micromagnetic Modeling of Perpendicular SOMA Media
Author :
Long, H.H. ; Ong, E.T. ; Xiao, P.Y. ; Liu, Z.J. ; Huang, K.L.
Author_Institution :
Hitachi Global Storage Technol.
Abstract :
This paper presents numerical simulation of the write and read process based on self-organized magnetic array (SOMA) media to study the particle-array misalignment effects on recording performances. The simulation is based on a three-dimensional finite element micromagnetic model of the media and an analytical model of the single pole perpendicular recording write field. The physical problem is modeled with a hybrid finite-element method-boundary-element method formulation, and the evaluation is accelerated using a new fast Fourier transform on multipoles method. The results show the lowest signal and signal-to-noise ratio occur at the best alignment situation, which is to be accepted as the intrinsic characteristic for SOMA media
Keywords :
arrays; boundary-elements methods; fast Fourier transforms; finite element analysis; magnetic materials; micromagnetics; perpendicular magnetic recording; 3D finite element model; FE-FFTM algorithm; fast Fourier transform; finite-element method-boundary-element method; hybrid FEM-BEM; micromagnetic modeling; multipoles method; perpendicular SOMA media; self-organized magnetic array; single pole perpendicular recording write; Anisotropic magnetoresistance; Assembly; Finite element methods; Magnetic anisotropy; Magnetostatics; Memory; Micromagnetics; Perpendicular magnetic anisotropy; Perpendicular magnetic recording; Signal to noise ratio; Fast Fourier transform on multipoles; SOMA; hybrid FEM-BEM; micromagnetic modeling;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2006.880109
