Abstract
The anomalous Hall effect (AHE) in quarternary Heusler-type Ni50Mn17Fe8Ga25 melt-spun ribbons is investigated. Experimental correlation between saturated anomalous Hall resistivity (rho(M)(A)(S)) and longitudinal resistivity (rho(xx)) is achieved for the low-temperature martensitic phase and the high-temperature austenitic phase as rho(M)(A)(S)infinity rho(n=4.2)(xx) and rho(M)(A)(S)infinity rho(n=2.1)(xx), respectively. The unexpectedly large exponent of n=4.2 in the martensitic phase is found to contradict the traditional theory of AHE with n=1-2, but it can be explained by a side-jump model beyond the short-range limit as a result of the intermediate-range spin-dependent electron scattering by relatively large Mn-rich clusters instead. The restoration of the exponent back to a normal value of n=2.1 in the austenitic phase is ascribed to the domination of the electron scattering by phonons, compared to that by the Mn-rich clusters, at elevated temperatures and with phonon softening in the transverse-acoustic TA(2) mode.