Namiki Wataru, Tsuchiya Takashi, Takayanagi Makoto, Higuchi Tohru, Terabe Kazuya
International Center for Materials Nanoarchitectonics (WPI-MANA), National Institute for Materials Science (NIMS), 1-1 Namiki, Tsukuba, Ibaraki 305-0044, Japan.
Department of Applied Physics, Faculty of Science, Tokyo University of Science, 6-3-1 Niijuku, Katsushika, Tokyo 125-8585, Japan.
ACS Nano. 2020 Nov 24;14(11):16065-16072. doi: 10.1021/acsnano.0c07906. Epub 2020 Nov 2.
An all-solid-state redox device, composed of magnetite (FeO) thin film and Li conducting electrolyte thin film, was fabricated for the manipulation of a magnetization angle at room temperature (RT). This is a key technology for the creation of efficient spintronics devices, but has not yet been achieved at RT by other carrier doping methods. Variations in magnetization angle and magnetic stability were precisely tracked through the use of planar Hall measurements at RT. The magnetization angle was reversibly manipulated at 10° by maintaining magnetic stability. Meanwhile, the manipulatable angle reached 56°, although the manipulation became irreversible when the magnetic stability was reduced. This large manipulation of magnetic angle was achieved through tuning of the 3d electron number and modulation of the internal strain in the FeO due to the insertion of high-density Li (approximately 10 cm). This RT manipulation is applicable to highly integrated spintronics devices due to its simple structure and low electric power consumption.
一种由磁铁矿(FeO)薄膜和锂导电电解质薄膜组成的全固态氧化还原器件,被制造用于在室温(RT)下操纵磁化角。这是创建高效自旋电子器件的一项关键技术,但通过其他载流子掺杂方法尚未在室温下实现。通过在室温下使用平面霍尔测量精确跟踪磁化角和磁稳定性的变化。通过保持磁稳定性,磁化角在10°时可逆地被操纵。同时,可操纵角度达到56°,尽管当磁稳定性降低时操纵变得不可逆。这种对磁角的大操纵是通过调整3d电子数以及由于插入高密度锂(约10 cm)而对FeO中的内应变进行调制来实现的。由于其结构简单和低功耗,这种室温操纵适用于高度集成的自旋电子器件。
