Thermomagnetic properties of amorphous rare-earth alloys with Fe, Ni, or Co

The magnetic properties and field-dependent specific heat of melt-spun amorphous RE(70)TM(30) (RE=Gd, Tb, Dy, Ho and Er; TM=Fe and Ni) and Gd65Co35 alloys were investigated as potential magnetic refrigerants. Essentially zero magnetic hysteresis was observed in all the Gd-TM alloys at temperatures from 5 K up to the ordering temperatures. The coercive force of the RE(70)TM(30) alloys depended mainly on the RE species and increased according to the order of RE=Gd<Ho<Er<Dy<Tb. The magnetic susceptibility of most of the alloys showed apparently normal Curie-Weiss behavior above the ordering temperatures, The heat capacity measurements in zero field and applied fields of 4 and 8 T indicated that the magnetic transition in these alloys are significantly broadened. The maximum adiabatic temperature changes for Er70Fe30, Gd70Ni30 and Gd65Co35 amorphous alloys in a field change of 8 T are 4.0, 3.4, and 3.0 K, respectively. Mossbauer spectroscopy revealed that Fe atoms in the amorphous RE(70)Fe(30) alloys carry a small magnetic moment that may complicate the magnetic ordering in the alloys, A simple model assuming a Gaussian distribution of ordering temperatures around the apparent Curie temperature was constructed to attempt to reconcile the differences in the observed magnetic properties of these amorphous alloys, The broad magnetic transition is attributed to the fluctuation of the exchange integral caused by the structural disorder in amorphous alloys. The calculated susceptibility, magnetization, and heat capacity agreed reasonably well with the experimental data and show that the magnetic susceptibility and magnetization are only weakly affected by the distribution of ordering temperatures, but the heat capacity is much more sensitive to such a distribution. To effectively screen out magnetic refrigerants with sharp magnetic transitions and correspondingly large adiabatic temperature changes from those with broadened transitions and small adiabatic temperature changes, the field-dependent heat capacity measurement technique is a powerful tool to use. (C) 1996 American Institute of Physics.