Quantum-Phase Electronics Center and Department of Applied Physics, The University of Tokyo , Tokyo 113-8656, Japan.
RIKEN Center for Emergent Matter Science (CEMS) , Wako 351-0198, Japan.
Nano Lett. 2017 Sep 13;17(9):5595-5599. doi: 10.1021/acs.nanolett.7b02420. Epub 2017 Aug 30.
Molecular beam epitaxy (MBE) provides a simple but powerful way to synthesize large-area high-quality thin films and heterostructures of a wide variety of materials including accomplished group III-V and II-VI semiconductors as well as newly developing oxides and chalcogenides, leading to major discoveries in condensed-matter physics. For two-dimensional (2D) materials, however, main fabrication routes have been mechanical exfoliation and chemical vapor deposition by making good use of weak van der Waals bonding nature between neighboring layers, and MBE growth of 2D materials, in particular on insulating substrates for transport measurements, has been limited despite its fundamental importance for future advanced research. Here, we report layer-by-layer epitaxial growth of scalable transition-metal dichalocogenide (TMDC) thin films on insulating substrates by MBE and demonstrate ambipolar transistor operation. The proposed growth protocol is broadly applicable to other TMDCs, providing a key milestone toward fabrication of van der Waals heterostructures with various 2D materials for novel properties and functionalities.
分子束外延 (MBE) 为合成大面积高质量的各种材料的薄膜和异质结构提供了一种简单而强大的方法,包括已实现的 III-V 和 II-VI 族半导体以及新兴的氧化物和硫族化物,从而在凝聚态物理领域取得了重大发现。然而,对于二维 (2D) 材料,主要的制造途径是机械剥离和化学气相沉积,充分利用了相邻层之间较弱的范德华键合性质,尽管对于未来的先进研究具有重要意义,但 2D 材料的 MBE 生长,特别是在用于传输测量的绝缘衬底上的生长,受到了限制。在这里,我们报告了通过 MBE 在绝缘衬底上进行可扩展的过渡金属二卤代物 (TMDC) 薄膜的逐层外延生长,并展示了双极性晶体管的工作。所提出的生长方案广泛适用于其他 TMDC,为制造具有各种二维材料的范德华异质结构以实现新颖的性能和功能提供了一个关键的里程碑。
