自旋电子学
石墨烯
共价键
纳米技术
自旋极化
化学
选择性
自旋(空气动力学)
材料科学
结晶度
化学物理
旋转阀
极化(电化学)
光电子学
金属有机骨架
电极
沉积(地质)
磁性
聚合物
作者
Enbing Zhang,Shuaishuai Ding,Guangyuan Feng,Jinhao Cheng,Li X,Liu Z,Xi Zhang,Yunzhe Ke,Shengbin Lei,W HU
摘要
Two-dimensional chiral covalent organic frameworks (2D-CCOFs) stand out as excellent candidates for chiral spintronic devices owing to their tailorable semiconducting structures and intrinsic chiral sites. However, two critical challenges currently hinder their development: first, the difficulty in synthesizing highly crystalline 2D-CCOF films and, second, the lack of reliable methods to construct stable 2D-CCOF-based spintronic devices. Herein, we successfully synthesized a 2D-CCOF film featuring a high crystallinity and excellent conductivity. In situ magnetic conductive-probe AFM (in situ mCP-AFM) characterization confirms that this 2D-CCOF exhibits excellent chiral-induced spin selectivity (CISS), with a spin polarization over 90% at room temperature. Using graphene as a blocking layer, we have successfully constructed stable half-spin valve devices based on the 2D-CCOF, which exhibit distinct chirality-dependent magnetoresistance. Graphene plays a key role in mitigating the detrimental effect of electrode deposition on the CCOF films. The excellent spin selectivity of 2D-CCOF opens up unprecedented opportunities for efficient control of electron spin and enables solid-state chiral spintronic devices.
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