Design of thermal hysteresis in nonstoichiometric alloys with giant magnetocaloric effect
Abstract
The non-stoichiometric Fe2P-type (FeMnP0.5Si0.5)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 ( SM); 15.7 J/kgK, at 2 T magnetic field for the x = 0 alloy. SM decreases with increasing x. Results from M\"ossbauer 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 SM. The thermal hysteresis ( Thyst) 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 Tad, which highly depends on Thyst, is 1.7 K at 1.9 T applied field for the x = 0.02 alloy.
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