异质结
材料科学
卤化物
极化(电化学)
自旋(空气动力学)
应变工程
接口(物质)
光电子学
自旋极化
凝聚态物理
格子(音乐)
金属
圆极化
残余物
化学物理
金属卤化物
纳米技术
过渡金属
作者
Jin Xiao,Yang Li,Yanan Liu,Jing Li,Li Fang,Haofeng Zheng,Yanlong Wang,Qi Liu,Xuyu Ma,Shuai Pang,Jing Hu,Jianbo Wang,Shaocong Hou
标识
DOI:10.1038/s41467-026-69455-4
摘要
Precise control of interfaces is crucial for spin generation, transport, and detection in opto-spintronics. However, the interface engineering for efficient spin injection remains a significant challenge. Here, we synthesized a helical structure of PbI2 (R-PbI2) via an interfacial chirality-induced growth approach at the heterostructure interface. This few-nanometer-thick R-PbI2 layer shows a lower lattice mismatch with both the adjacent R-NEAPbI3 (R-NEA refers to R-1-(1-naphtyl)ethylamine) and PbI2 layers, and leads to an optimal chiral interface in the chiral heterostructure with minimized residual strain and defect density. Combined with circularly polarized pump-probe spectroscopic and spin-photovoltaic measurements, our chiral heterostructure interface contributes a spin-injection efficiency up to 68%, thus leading to a degree of polarization of 29% in photocurrent. The precise synthesis of a chiral interface offers a promising route to manipulate spin dynamics and achieve a high degree of spin polarization required for advanced opto-spintronic applications. The authors demonstrated a chiral R-PbI2 interface in metal halides heterostructure that yields 68% spin-injection efficiency and 29% polarization in photocurrent. This precision engineering provides a vital pathway for efficient opto-spintronics.
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