铁磁性
凝聚态物理
范德瓦尔斯力
领域(数学)
交换偏差
材料科学
物理
磁场
量子力学
磁化
数学
磁各向异性
分子
纯数学
作者
Jifeng Shao,Xiaolong Yin,C. W. Bao,Sirong Lu,Xiaoming Ma,Shu Guo,Le Wang,Xi Zhang,Zhiyue Li,Longxiang Li,Yue Zhao,Tingyong Chen
标识
DOI:10.48550/arxiv.2406.02260
摘要
Exchange bias (EB) is a cornerstone of modern magnetic memory and sensing technologies. Its extension to the realm of two-dimensional (2D) van der Waals (vdW) magnets holds promise for revolutionary advancements in miniaturized and efficient atomic spintronic devices. However, the blocking temperature of EB in 2D vdW magnets is currently well below room temperature ~130 K. This study reports a robust EB phenomenon in Fe3GaTe2 thin-layer devices, which significantly increases the blocking temperature to a near-room-temperature record of 280 K. Both the bias direction and magnitude can be isothermally tuned by adjusting the field sweep range, in striking contrast to the conventional EB in ferromagnetic/antiferromagnetic (FM/AFM) bilayers. We propose an exchange spring model in which crystal defects with higher coercivity act as the pivotal pinning source for the observed EB phenomenon, deviating from the conventional FM/AFM interface mechanism. Cumulative growth of minor loops and multiple magnetization reversal paths are observed in field cycles below the saturation field, consistent with the hard FM defects behavior of our exchange spring model. These findings provide insights into the complex magnetic order in 2D ferromagnets and open new avenues for developing practical ultrathin vdW spintronic devices with EB-like properties at room temperature.
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