用二硅化钼涂覆衬底温度控制的分子束外延生长低带隙材料厚膜

IF 1.4 4区工程技术

Journal of Vacuum Science & Technology B Pub Date : 2021-01-06 DOI:10.1116/6.0000713

A. Podpirka, Michael C. Brupbacher, Christine M. Zgrabik, Jarod C. Gagnon, D. Shrekenhamer

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引用次数: 0

摘要

分子束外延(MBE)沉积允许材料的外延生长需要纳米厚度层的原子精确控制。通过MBE在较大带隙衬底上生长较小带隙材料的一个关键问题是沉积层与加热器的辐射耦合，如果不适当调节，可能导致温度不受控制的升高。在这项工作中，我们证明了通过加入二硅化钼涂层钼背板将加热器的辐射成分与衬底和层沉积解耦的能力。我们证明，这种新型涂层可以与加热器高效耦合，同时在生长表面提供更好的温度控制，从而实现稳定的生长条件。我们通过在(100)砷化镓衬底上生长碲化锗薄膜，证明了碲化锗薄膜的稳定生长和薄膜特性。

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Molecular beam epitaxy growth of low-bandgap material thick films using a molybdenum disilicide coated backing plate for substrate temperature control

Molecular beam epitaxial (MBE) deposition allows for the epitaxial growth of materials requiring atomically precise control of nanometer thick layers. A key concern with the growth of smaller bandgap materials on larger bandgap substrates via MBE is the radiative coupling of the deposited layer with the heater, which can lead to uncontrolled increases in temperature if not properly accommodated for. In this work, we demonstrate the ability to decouple the radiative component of the heater with the substrate and layer deposition through the incorporation of a molybdenum disilicide coated molybdenum backing plate. We demonstrate that the novel coating allows for highly efficient coupling with the heater while providing improved temperature control at the growth surface, leading to stable growth conditions. We demonstrate the stable growth and film characteristics through the growth of germanium telluride thin films on (100) gallium arsenide substrates.

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来源期刊

Journal of Vacuum Science & Technology B 工程技术-工程：电子与电气

自引率

14.30%

发文量

审稿时长

2.5 months

期刊介绍： Journal of Vacuum Science & Technology B emphasizes processing, measurement and phenomena associated with micrometer and nanometer structures and devices. Processing may include vacuum processing, plasma processing and microlithography among others, while measurement refers to a wide range of materials and device characterization methods for understanding the physics and chemistry of submicron and nanometer structures and devices.