Effect of Phase Transition Type on the Magnetocaloric Effect and Magnetic Hysteresis in Er(Co1-xMnx)2 Laves Alloys

IF 1.6 4区物理与天体物理 Q3 PHYSICS, APPLIED Journal of Superconductivity and Novel Magnetism Pub Date : 2024-12-18 DOI:10.1007/s10948-024-06888-2

H. Y. Dai, Z. H. Zu, Y. K. Chu, R. J. Cui, Z. D. Han

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Abstract

As magnetic refrigerants, first-order transition (FOT) and second-order transition (SOT) materials possess distinct advantages and disadvantages. If the phase transition can be tuned to the critical point between FOT and SOT, it may be possible to combine the benefits of both, thereby achieving an outstanding magnetocaloric effect. Here, we demonstrated this approach through phase transition engineering in Er(Co_1-xMn_x)₂ alloys. When x ≤ 0.06, the magnetic phase transition of the samples was FOT, exhibiting a significant magnetic entropy change. However, at x = 0.08, the samples underwent a SOT from ferromagnetic to paramagnetic, leading to a substantial reduction in the magnetocaloric effect. At the critical point of the FOT/SOT border with x = 0.06, the sample exhibited a large magnetic entropy change along with negligible magnetic hysteresis. This work demonstrates that the critical point between FOT and SOT is an effective means of achieving an excellent magnetocaloric effect.

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相变类型对Er(Co1-xMnx)2合金磁热效应和磁滞的影响

作为磁性制冷剂，一阶过渡（FOT）和二阶过渡（SOT）材料各有优缺点。如果相变可以调整到FOT和SOT之间的临界点，就有可能将两者的优点结合起来，从而实现出色的磁热效应。在这里，我们通过Er(Co1-xMnx)2合金的相变工程证明了这种方法。当x≤0.06时，样品的磁相变为FOT，表现出明显的磁熵变化。然而，当x = 0.08时，样品经历了从铁磁性到顺磁性的SOT，导致磁热效应大幅降低。在FOT/SOT边界x = 0.06的临界点处，样品表现出较大的磁熵变化，磁滞可以忽略不计。这项工作表明，在FOT和SOT之间的临界点是实现优异磁热效应的有效手段。

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来源期刊

Journal of Superconductivity and Novel Magnetism 物理-物理：凝聚态物理

CiteScore

3.70

自引率

11.10%

发文量

342

审稿时长

3.5 months

期刊介绍： The Journal of Superconductivity and Novel Magnetism serves as the international forum for the most current research and ideas in these fields. This highly acclaimed journal publishes peer-reviewed original papers, conference proceedings and invited review articles that examine all aspects of the science and technology of superconductivity, including new materials, new mechanisms, basic and technological properties, new phenomena, and small- and large-scale applications. Novel magnetism, which is expanding rapidly, is also featured in the journal. The journal focuses on such areas as spintronics, magnetic semiconductors, properties of magnetic multilayers, magnetoresistive materials and structures, magnetic oxides, etc. Novel superconducting and magnetic materials are complex compounds, and the journal publishes articles related to all aspects their study, such as sample preparation, spectroscopy and transport properties as well as various applications.