Nonlinear analysis of magnetic liquid free surface deformation in a 3D space

Abstract

Abstract The nonlinear analysis of magnetic liquid free surface deformation under the influence of a static vertically oriented magnetic field produced by a pair of Helmholtz coils in a 3D space is presented in the article. The hexagonal pattern of peaks resulting from the Rosensweig or normal instability, occurs when the magnetization of the magnetic liquid exceeds the critical value. To predict the amplitudes and distance between peaks in the pattern, nonlinear analysis should be performed with employed higher order terms in the mean curvature expression of the free surface. The computational strategy presented in the article is divided into two stages. At the first stage, the magnetic field in the 3D space is calculated by the FEM based software Opera Field, while the second stage is devoted to determining the surface profile by minimizing the energy functional using a Differential Evolution algorithm in Matlab. The amplitudes of the central spike and wave number have been computed for the various values of the excitation magnetic field.