Abstract
Magnetostructural coupling, which is the coincidence of crystallographic and magnetic transition, has obtained intense attention for its abundant magnetoresponse effects and promising technological applications, such as solid-state refrigeration, magnetic actuators and sensors. The hexagonal Ni2In-type compounds have attracted much attraction due to the strong magnetostructural coupling and the resulted giant negative thermal expansion and magnetocaloric effect. However, the as-prepared samples are quite brittle and naturally collapse into powders. Here, we report the effect of particle size on the magnetostructural coupling and magnetocaloric effect in the Ni2In-type Mn-Fe-Ni-Ge compound, which undergoes a large lattice change across the transformation from paramagnetic austenite to ferromagnetic martensite. The disappearance of martensitic transformation in a large amount of austenitic phase with reducing particle size, to our best knowledge, has not been reported up to now. The ratio can be as high as 40.6% when the MnNi0.8Fe0.2Ge bulk was broken into particles in the size range of 5~15 μm. Meanwhile, the remained magnetostructural transition gets wider and the magnetic hysteresis becomes smaller. As a result, the entropy change drops, but the effective cooling power RCeffe increases and attains to the maximum at particles in the range of 20~40 μm. These observations provide constructive information and highly benefit practical applications for this class of novel magnetoresponse materials.
Highlights
IntroductionThe stoichiometric MnNiGe, a member of MM’X family, does not show magnetostructural coupling
MM’X (M, M’ = transition metals, X = Si, Ge, Sn) compound with hexagonal Ni2In-type structure is another material that attracted much attention due to the strong magnetostructural coupling[13,14,15,16]
Magnetization measurements indicated that the prepared Mn1−xFexNiGe and MnNi1−yFeyGe bulk show magnetostructural transition at Fe concentration 0.08 ≤ x ≤ 0.26, 0.20 ≤ y ≤ 0.30, consistent with previous report[16]
Summary
The stoichiometric MnNiGe, a member of MM’X family, does not show magnetostructural coupling It undergoes a martensitic structural transformation from Ni2In-type austenite to TiNiSi-type martensite at Tstru~470 K, and a separate magnetic transition at lower temperature of TNM~346K. We report the particle size effect of magnetostructural coupling and MCE in the hexagonal Ni2In-type Mn-Fe-Ni-Ge compounds. This class of materials is unique, whose magnetostructural transition is sensitive to pressure rather than magnetic field[15,21]. A large amount of austenitic phase loses the martensitic transformation, i.e. magnetostructural transition, and retains the hexagonal FM structure in the entire temperature range. The entropy change drops, the effective cooling power (RCP) increases by 22% as the bulk was broken into particles in the size range of 20~40 μ m
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