Design of thermal hysteresis in nonstoichiometric alloys with giant magnetocaloric effect

TL;DR

This study investigates non-stoichiometric FeMnPSiV alloys for magnetic refrigeration, focusing on how varying V content affects magnetic transition properties, entropy change, and thermal hysteresis near room temperature.

Contribution

It provides new insights into tuning magnetocaloric properties and hysteresis in Fe-based alloys through V substitution, enhancing their potential for practical magnetic cooling applications.

Findings

Magnetic ordering temperature decreases with V content.

Large magnetocaloric effect observed at low fields.

Thermal hysteresis reduces with increasing V concentration.

Abstract

The non-stoichiometric Fe$_2$P-type (FeMnP$_{0.5}$Si$_{0.5}$)$_{1-x}$(FeV)$_{x}$ alloys ( $x=0, 0.01$, $0.02$, and $0.03$) have been investigated as potential candidates for magnetic refrigeration near room temperature. The magnetic ordering temperature decreases with increasing FeV concentration, $x$, which can be ascribed to decreased ferromagnetic coupling strength between the magnetic atoms. The strong magnetoelastic coupling in these alloys results in large values of the isothermal entropy change ($\Delta S_M$); $15.7$ J/kgK, at $2$ T magnetic field for the $x = 0$ alloy. $\Delta S_M$ decreases with increasing $x$. Results from M{\"o}ssbauer spectroscopy reveal that the average hyperfine field (in the ferromagnetic state) and average center shift (in the paramagnetic state) have the same decreasing trend as $\Delta S_M$. The thermal hysteresis ($\Delta T_{hyst}$) of the magnetic phase transition decreases with increasing $x$, while the mechanical stability of the alloys improves due to the reduced lattice volume change across the magnetoelastic phase transition. The adiabatic temperature change $\Delta T_{ad}$, which highly depends on $\Delta T_{hyst}$, is $1.7$ K at $1.9$ T applied field for the $x = 0.02$ alloy.