Foams-To-Films: A Facile Approach Towards Space-Confined CVD Growth of MoS2.

IF 2.3 3区 化学 Q3 CHEMISTRY, PHYSICAL
Taylor M Currie, Jesse Davalos Barrios, Moc Lan Nguyen, Laurene Tetard, Titel Jurca
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引用次数: 0

Abstract

2D materials have rapidly become the building blocks for the next generation of semiconducting materials and devices, with chemical vapor deposition (CVD) emerging as a prefered method for their synthesis. However, the predictable and reproducible growth of high quality, large 2D monolayers remains challenging. An important facet is controlling the local environment at the surface of the substrate - here, space-confinement techniques have emerged as promising candidates. We demonstrate that space-confined CVD growth using microstructured MoOx grown on Ni foam is an appealing approach for rapid growth of high quality MoS2 monolayers; a very important subset of 2D materials. This method eschews the use of powders which can be more difficult to control. By incorporation of a porous barrier in the Ni foam support, the rate of delivery of both the Mo and S source to the substrate is dampened, leading to coverage of large, high quality, mono-to-few layer triangular domains as confirmed by Raman and photoluminescence (PL) spectroscopies together with atomic force microscopy (AFM) height measurements.

泡沫到薄膜:实现 MoS2 空间约束 CVD 生长的简便方法。
二维材料已迅速成为下一代半导体材料和设备的基石,化学气相沉积(CVD)成为合成二维材料的首选方法。然而,高质量、大面积二维单层材料的可预测和可重现生长仍然具有挑战性。一个重要的方面是控制基底表面的局部环境--在这方面,空间约束技术已成为有前途的候选方法。我们证明,使用生长在镍泡沫上的微结构氧化钼进行空间约束 CVD 生长,是快速生长高质量 MoS2 单层的一种极具吸引力的方法;MoS2 是二维材料中一个非常重要的子集。这种方法避免了使用更难控制的粉末。通过在镍泡沫衬底中加入多孔阻挡层,钼源和硒源向衬底的传输速度得到抑制,从而覆盖了大面积、高质量、单层到几层的三角形畴,拉曼光谱、光致发光 (PL) 光谱以及原子力显微镜 (AFM) 高度测量均证实了这一点。
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来源期刊
Chemphyschem
Chemphyschem 化学-物理:原子、分子和化学物理
CiteScore
4.60
自引率
3.40%
发文量
425
审稿时长
1.1 months
期刊介绍: ChemPhysChem is one of the leading chemistry/physics interdisciplinary journals (ISI Impact Factor 2018: 3.077) for physical chemistry and chemical physics. It is published on behalf of Chemistry Europe, an association of 16 European chemical societies. ChemPhysChem is an international source for important primary and critical secondary information across the whole field of physical chemistry and chemical physics. It integrates this wide and flourishing field ranging from Solid State and Soft-Matter Research, Electro- and Photochemistry, Femtochemistry and Nanotechnology, Complex Systems, Single-Molecule Research, Clusters and Colloids, Catalysis and Surface Science, Biophysics and Physical Biochemistry, Atmospheric and Environmental Chemistry, and many more topics. ChemPhysChem is peer-reviewed.
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