Hall effect in amorphous thin-film magnetic alloys

Abstract

Amorphous magnetic alloys have unusually large extraordinary Hall coefficients (R_s) defined by the ratio of the Hall resistivity to the net magnetic moment of the alloy. We have studied the Hall effect in amorphous films in the ternary ferrimagnetic systems Co‐Gd‐Mo and Co‐Gd‐Au, alloys which exhibit compensation temperatures (T_comp). Above T_comp the Hall coefficient R_s is positive and below T_comp the sign of R_s changes to negative in a discontinuous manner, probably limited by the homogeneity of the sample. We have also prepared amorphous Gd‐Au and Y‐Co films and measured R_s which we use to qualitatively separate the effects of the Co and Gd sublattices in the ternary alloys. We attribute the sign of R_s to a combined effect of a negative Gd and a positive Co Hall coefficient. Above T_comp the Co is dominant and points in the direction of the applied field H while Gd is antiparallel to H. Thus, both sublattices contribute in a positive sense to R_s. Below T_comp the Gd moment is dominant and the sign of R_s is reversed for both sublattices. Values of R_s up to 25×10⁻⁹ Ω cm/G are measured near T_comp and when Mo is present R_s is reduced to 5×10⁻⁹ Ω cm/G. Molybdenum is known to cause a strong decrease in the moment of the cobalt sublattice and this probably is the reason R_s decreases. Our interpretation of the Hall effect in these ferrimagnetic systems differs from other recently proposed models.