Advanced magnetocaloric microwires: What does the future hold?

Hong-Xian Shen, N.T.M. Duc, H. Belliveau, Lin Luo, Yunfei Wang, Jian-Fei Sun, Faxiang Qin, M. Phan
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Abstract

Magnetic refrigeration (MR) based on the magnetocaloric effect (MCE) is a promising alternative to conventional vapor compression refrigeration techniques. The cooling efficiency of a magnetic refrigerator depends on its refrigeration capacity and operation frequency. Existing refrigerators possess limited cooling efficiency due to the low operating frequency (around tens of Hz). Theory predicts that reducing geometrical effects can increase the operation frequency by reducing the relaxation time of a magnetic material. As compared to other shapes, magnetocaloric wires transfer heat most effectively to a surrounding environment, due to their enhanced surface area. The wire shape also yields a good mechanical response, reducing the relaxation time and consequently increasing the operation frequency of the cooling device. Experiments have validated the theoretical predictions. By assembling microwires with different magnetocaloric properties and Curie temperatures into a laminate structure, a table-like magnetocaloric bed can be created and used as an active cooling device for micro-electro-mechanical system (MEMS) and nano-electro-mechanical system (NEMS). This paper assesses recent progress in the development of magnetocaloric microwires and sheds light on the important factors affecting the magnetocaloric behavior and cooling efficiency in microwire systems. Challenges, opportunities, and strategies regarding the development of advanced magnetocaloric microwires are also discussed.
先进的磁性微丝:未来会怎样?
基于磁致效应(MCE)的磁制冷(MR)是传统蒸汽压缩制冷技术的一种很有前途的替代技术。磁制冷器的制冷效率取决于其制冷能力和运行频率。由于工作频率较低(约几十赫兹),现有冰箱的冷却效率有限。理论预测,减少几何效应可以通过缩短磁性材料的弛豫时间来提高工作频率。与其他形状相比,磁致导线的表面积更大,因此能最有效地将热量传递到周围环境中。此外,磁致导线的形状还能产生良好的机械响应,缩短弛豫时间,从而提高冷却装置的工作频率。实验验证了理论预测。通过将具有不同磁致性能和居里温度的微线组装成层压结构,可以创建一个类似桌子的磁致床,并将其用作微机电系统(MEMS)和纳米机电系统(NEMS)的主动冷却装置。本文评估了磁致微线开发的最新进展,并揭示了影响微线系统磁致行为和冷却效率的重要因素。本文还讨论了开发先进磁致伸缩微线所面临的挑战、机遇和策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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