Xue Hao-Pu, Sun Rui, Yang Xu, Comstock Andrew, Liu Yangrui, Ge Binghui, Liu Jia-Nan, Wei Yan-Sheng, Yang Qing-Lin, Gai Xue-Song, Gong Zi-Zhao, Xie Zong-Kai, Li Na, Sun Dali, Zhang Xiang-Qun, He Wei, Cheng Zhao-Hua
Beijing National Laboratory for Condensed Matter Physics, Institute of Physics, Chinese Academy of Sciences, Beijing, 100190, China.
School of Physical Sciences, University of Chinese Academy of Sciences, Beijing, 100049, China.
Adv Mater. 2023 Mar;35(9):e2208343. doi: 10.1002/adma.202208343. Epub 2023 Jan 18.
Dual topological insulators, simultaneously protected by time-reversal symmetry and crystalline symmetry, open great opportunities to explore different symmetry-protected metallic surface states. However, the conventional dual topological states located on different facets hinder integration into planar opto-electronic/spintronic devices. Here, dual topological superlattices (TSLs) Bi Se -(Bi /Bi Se ) with limited stacking layer number N are constructed. Angle-resolved photoelectron emission spectra of the TSLs identify the coexistence and adjustment of dual topological surface states on Bi Se facet. The existence and tunability of spin-polarized dual-topological bands with N on Bi Se facet result in an unconventionally weak antilocalization effect (WAL) with variable WAL coefficient α (maximum close to 3/2) from quantum transport experiments. Most importantly, it is identified that the spin-polarized surface electrons from dual topological bands exhibit circularly and linearly polarized photogalvanic effect (CPGE and LPGE). It is anticipated that the stacked dual-topology and stacking layer number controlled bands evolution provide a platform for realizing intrinsic CPGE and LPGE. The results show that the surface electronic structure of the dual TSLs is highly tunable and well-regulated for quantum transport and photoexcitation, which shed light on engineering for opto-electronic/spintronic applications.
双重拓扑绝缘体同时受到时间反演对称性和晶体对称性的保护,为探索不同的对称性保护金属表面态提供了绝佳机会。然而,位于不同晶面的传统双重拓扑态阻碍了其集成到平面光电器件/自旋电子器件中。在此,构建了具有有限堆叠层数N的双重拓扑超晶格(TSL)Bi₂Se₃-(Bi₂Te₃/Bi₂Se₃)。TSL的角分辨光电子能谱确定了Bi₂Se₃晶面上双重拓扑表面态的共存和调控。Bi₂Se₃晶面上具有N的自旋极化双重拓扑能带的存在和可调性,导致量子输运实验中出现具有可变反弱局域化系数α(最大值接近3/2)且反常微弱的反弱局域化效应(WAL)。最重要的是,已确定来自双重拓扑能带的自旋极化表面电子表现出圆偏振和线性偏振光电流效应(CPGE和LPGE)。预计堆叠的双重拓扑和堆叠层数控制的能带演化将为实现本征CPGE和LPGE提供一个平台。结果表明,双重TSL的表面电子结构对于量子输运和光激发具有高度可调性和良好的调控性,这为光电器件/自旋电子器件应用的工程设计提供了启示。
