应用于空间太阳能电池的分子束外延生长在Ge衬底上的反相无畴GaAs

Conference Record of the Twenty Sixth IEEE Photovoltaic Specialists Conference - 1997 Pub Date : 1997-09-29 DOI:10.1109/PVSC.1997.654208

S. Ringel, R. Sieg, S. Ting, E. Fitzgerald

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引用次数: 11

摘要

消除反相畴(APDs)、螺纹位错和不受控制的界面扩散是实现Ge多带隙III-V太阳能电池最大设计灵活性和高效率的关键考虑因素。在本文中，我们确定了消除这些问题的关键生长步骤，并提出了一种最佳的分子束外延(MBE)生长过程，该过程可以产生无apd，近无位错的GaAs/Ge，并且大大抑制了GaAs覆盖层和Ge衬底中的相互扩散。对于固体源MBE，消除apd需要双台阶、清洁的Ge表面和由完整的单层As或Ga组成的预层。通过实时现场监测，可以观察和维持正确的条件，以确保再现性。通过迁移增强外延在低温下启动生长，实际上消除了Ge向GaAs的扩散和Ga向Ge的扩散，而As向Ge的扩散基本上受到抑制。

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Anti-phase domain-free GaAs on Ge substrates grown by molecular beam epitaxy for space solar cell applications

Elimination of anti-phase domains (APDs), threading dislocations and uncontrolled interface diffusion are critical considerations for achieving maximum design flexibility and high efficiency in multi-bandgap III-V solar cells on Ge. In this paper, we identify critical growth steps to eliminate each of these problems and present an optimum molecular beam epitaxy (MBE) growth procedure which yields APD-free, near-dislocation-free GaAs/Ge with greatly suppressed interdiffusion in both the GaAs overlayer and Ge substrate. For solid source MBE, elimination of APDs requires a double-stepped, clean Ge surface and a prelayer consisting of a complete monolayer of either As or Ga. Correct conditions can be observed and maintained by real-time in-situ monitoring to ensure reproducibility. Initiating growth at low temperature with migration enhanced epitaxy virtually eliminates Ge diffusion into GaAs and Ga diffusion into Ge, while As diffusion into Ge is substantially suppressed.

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Conference Record of the Twenty Sixth IEEE Photovoltaic Specialists Conference - 1997

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