Jia Liang , Qing Ai , Xiewen Wen , Xiuyu Tang , Tianshu Zhai , Rui Xu , Xiang Zhang , Qiyi Fang , Christine Nguyen , Yifeng Liu , Hanyu Zhu , Tanguy Terlier , Gary P. Wiederrecht , Pulickel M. Ajayan , Xiaofeng Qian , Jun Lou
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Here, we report a two-step vapor phase growth process for the creation of high-quality vdW heterostructures based on perovskites and TMDCs, such as 2D Cs<sub>3</sub>Bi<sub>2</sub>I<sub>9</sub>/MoSe<sub>2</sub>, with a large lattice mismatch. Supported by experimental and theoretical investigations, we discover that the Cs<sub>3</sub>Bi<sub>2</sub>I<sub>9</sub>/MoSe<sub>2</sub> vdW heterostructure possesses hybrid band alignments consisting of type-I and type-II heterojunctions because of the existence of defect energy levels in Cs<sub>3</sub>Bi<sub>2</sub>I<sub>9</sub>. More importantly, we demonstrate that the type-II heterojunction in the Cs<sub>3</sub>Bi<sub>2</sub>I<sub>9</sub>/MoSe<sub>2</sub> vdW heterostructure not only shows a higher interlayer exciton density, but also exhibits a longer interlayer exciton lifetime than traditional 2D TMDCs based type-II heterostructures. We attribute this phenomenon to the reduced overlap of electron and hole wavefunctions caused by the large lattice mismatch. 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引用次数: 0
摘要
二维(2D)范德华(vdW)异质结构为探索纳米尺度的新型物理和从电子学、光子学到光电子学的各种应用提供了新的平台。迄今为止的研究主要集中在通过机械剥离法制备的基于过渡金属二掺杂物(TMDCs)的样品上,因此研究使用多功能方法制备的新型材料的高质量 vdW 异质结构具有重要意义。在此,我们报告了一种基于包晶石和 TMDC(如具有较大晶格失配的二维 Cs3Bi2I9/MoSe2)的高质量 vdW 异质结构的两步气相生长工艺。在实验和理论研究的支持下,我们发现由于 Cs3Bi2I9 中存在缺陷能级,Cs3Bi2I9/MoSe2 vdW 异质结构具有由 I 型和 II 型异质结组成的混合带排列。更重要的是,我们证明了 Cs3Bi2I9/MoSe2 vdW 异质结构中的 II 型异质结不仅具有更高的层间激子密度,而且与传统的基于二维 TMDCs 的 II 型异质结构相比,具有更长的层间激子寿命。我们将这一现象归因于晶格失配导致的电子和空穴波函数重叠减少。我们的工作证明,直接生长基于完全不同材料的高质量 vdW 异质结构是可能的,这为探索新物理学和尖端应用(如光电子学、谷电学和高温超流)提供了前景广阔的平台。
Strong interlayer coupling and long-lived interlayer excitons in two-dimensional perovskite derivatives and transition metal dichalcogenides van der Waals heterostructures
Two-dimensional (2D) van der Waals (vdW) heterostructures offer new platforms for exploring novel physics and diverse applications ranging from electronics and photonics to optoelectronics at the nanoscale. The studies to date have largely focused on transition-metal dichalcogenides (TMDCs) based samples prepared by mechanical exfoliation method, therefore it is of significant interests to study high-quality vdW heterostructures using novel materials prepared by a versatile method. Here, we report a two-step vapor phase growth process for the creation of high-quality vdW heterostructures based on perovskites and TMDCs, such as 2D Cs3Bi2I9/MoSe2, with a large lattice mismatch. Supported by experimental and theoretical investigations, we discover that the Cs3Bi2I9/MoSe2 vdW heterostructure possesses hybrid band alignments consisting of type-I and type-II heterojunctions because of the existence of defect energy levels in Cs3Bi2I9. More importantly, we demonstrate that the type-II heterojunction in the Cs3Bi2I9/MoSe2 vdW heterostructure not only shows a higher interlayer exciton density, but also exhibits a longer interlayer exciton lifetime than traditional 2D TMDCs based type-II heterostructures. We attribute this phenomenon to the reduced overlap of electron and hole wavefunctions caused by the large lattice mismatch. Our work demonstrates that it is possible to directly grow high-quality vdW heterostructures based on entirely different materials which provide promising platforms for exploring novel physics and cutting-edge applications, such as optoelectronics, valleytronics, and high-temperature superfluidity.
期刊介绍:
Materials Today is the leading journal in the Materials Today family, focusing on the latest and most impactful work in the materials science community. With a reputation for excellence in news and reviews, the journal has now expanded its coverage to include original research and aims to be at the forefront of the field.
We welcome comprehensive articles, short communications, and review articles from established leaders in the rapidly evolving fields of materials science and related disciplines. We strive to provide authors with rigorous peer review, fast publication, and maximum exposure for their work. While we only accept the most significant manuscripts, our speedy evaluation process ensures that there are no unnecessary publication delays.