| Literature DB >> 35822066 |
Shanshan Liu1, Zihan Li1, Ke Yang2, Enze Zhang1, Awadhesh Narayan3, Xiaoqian Zhang4, Jiayi Zhu5, Wenqing Liu6, Zhiming Liao7, Masaki Kudo8, Takaaki Toriyama8, Yunkun Yang1, Qiang Li1, Linfeng Ai1, Ce Huang1, Jiabao Sun6, Xiaojiao Guo9, Wenzhong Bao9, Qingsong Deng10, Yanhui Chen10, Lifeng Yin1, Jian Shen1, Xiaodong Han10, Syo Matsumura8, Jin Zou7, Yongbing Xu4, Xiaodong Xu5, Hua Wu1, Faxian Xiu1.
Abstract
Two-dimensional (2D) ferromagnetic materials have been discovered with tunable magnetism and orbital-driven nodal-line features. Controlling the 2D magnetism in exfoliated nanoflakes via electric/magnetic fields enables a boosted Curie temperature (T C) or phase transitions. One of the challenges, however, is the realization of high T C 2D magnets that are tunable, robust and suitable for large scale fabrication. Here, we report molecular-beam epitaxy growth of wafer-scale Fe3+XGeTe2 films with T C above room temperature. By controlling the Fe composition in Fe3+XGeTe2, a continuously modulated T C in a broad range of 185-320 K has been achieved. This widely tunable T C is attributed to the doped interlayer Fe that provides a 40% enhancement around the optimal composition X = 2. We further fabricated magnetic tunneling junction device arrays that exhibit clear tunneling signals. Our results show an effective and reliable approach, i.e. element doping, to producing robust and tunable ferromagnetism beyond room temperature in a large-scale 2D Fe3+XGeTe2 fashion.Entities:
Keywords: 2D ferromagnetic material; Fe3+XGeTe2 film; TC tunability; above room temperature; element doping
Year: 2021 PMID: 35822066 PMCID: PMC9270067 DOI: 10.1093/nsr/nwab117
Source DB: PubMed Journal: Natl Sci Rev ISSN: 2053-714X Impact factor: 23.178