Above-room-temperature giant thermal conductivity switching in spintronic multilayers

H. Nakayama, Bin Xu, S. Iwamoto, K. Yamamoto, R. Iguchi, A. Miura, T. Hirai, Y. Miura, Y. Sakuraba, J. Shiomi, K. Uchida
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引用次数: 10

Abstract

Thermal switching provides an effective way for active heat flow control, which has recently attracted increasing attention in terms of nanoscale thermal management technologies. In magnetic and spintronic materials, the thermal conductivity depends on the magnetization configuration: this is the magneto-thermal resistance effect. Here we show that an epitaxial Cu/Co$_{50}$Fe$_{50}$ multilayer film exhibits giant magnetic-field-induced modulation of the cross-plane thermal conductivity. The magneto-thermal resistance ratio for the Cu/Co$_{50}$Fe$_{50}$ multilayer reaches 150% at room temperature, which is much larger than the previous record high. Although the ratio decreases with increasing the temperature, the giant magneto-thermal resistance effect of ~100% still appears up to 400 K. The magnetic field dependence of the thermal conductivity of the Cu/Co$_{50}$Fe$_{50}$ multilayer was observed to be about twice greater than that of the cross-plane electrical conductivity. The observation of the giant magneto-thermal resistance effect clarifies a potential of spintronic multilayers as thermal switching devices.
自旋电子多层中的室温以上巨热导率开关
热开关为主动热流控制提供了一种有效的方法,近年来在纳米尺度热管理技术中受到越来越多的关注。在磁性和自旋电子材料中,热导率取决于磁化结构:这是磁热阻效应。在这里,我们证明了外延Cu/Co$_{50}$Fe$_{50}$多层膜表现出巨大的磁场诱导的跨平面热导率调制。Cu/Co$_{50}$Fe$_{50}$多层膜的磁热阻比在室温下达到150%,远远大于之前的最高记录。尽管该比值随温度的升高而减小,但在400 K时仍出现~100%的巨磁热阻效应。Cu/Co$_{50}$Fe$_{50}$多层膜的导热系数对磁场的依赖性约为其平面电导率的两倍。巨磁热阻效应的观察阐明了自旋电子多层材料作为热开关器件的潜力。
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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