Studies of the Propagation Velocity of a Ferromagnetic Domain Boundary

Experimental results are given on the velocity of propagation of a single domain boundary in a crystal of silicon iron with a simple domain structure. In weak applied magnetic fields (0. 003 oersted) the velocity is given by a relation of the form v=G (H-H₀), where G is a constant 4 cm/sec. /oersted in this crystal, and H₀0. 003 oersted is the starting field. Calculation of the eddy current losses accompanying the motion of a plane boundary gives a theoretical expression for G in good agreement with experimental values; the predicted linear dependence on the resistivity was approximately verified by measurements at 78^, 194^, and 293^. In stronger fields (>5 oersteds) there is evidence that the wall closes on itself, and the experimental velocity of collapse of the wall as deduced from flux changes agrees with the theoretical result based on a model of eddy current losses accompanying a collapsing cylindrical boundary. The results have a bearing on the well-known eddy current anomaly, namely, the fact that the total loss in a ferromagnetic material undergoing a. c. magnetization is often two or three times larger than the eddy-current and hysteresis losses calculated in the usual way assuming a spatially uniform and isotropic classical permeability.