Technical advantages and challenges for core-shell micro/ nanowire large area PV devices

2010 35th IEEE Photovoltaic Specialists Conference Pub Date : 2010-06-20 DOI:10.1109/PVSC.2010.5617199

B. Wacaser, M. Khayyat, M. Reuter, D. Sadana, F. Ross

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引用次数: 7

Abstract

A promising field for future low cost, medium efficiency solar cell devices is the use of vapor-liquid-solid (VLS) grown nanowires or micropillars (NWs referring to both) as the active region of large scale (greater than 1 mm2 area) photovoltaic devices. There are several advantages of using NWs. The NWs can be doped as grown, helping with formation of a PV structure. NW-based PV structures require shorter carrier diffusion distances than are needed for a similarly thick planar absorber layer. At the same time, due to scattering and other optical phenomena the NW structure is able to trap more light and improve the overall light absorption. This, combined with the ability to grow nanowires on cheap substrates or reuse the growth substrate multiple times, makes NWs promising for future generation PV devices. In order for NWs to perform to their full potential several technical challenges need to be overcome. In this paper we will discuss these technical challenges in conjunction with the advantages of using NWs in large scale PV devices. We will also outline the progress that we and others have made in overcoming these challenges on the way to making nanowires a viable PV technology.

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核壳型微纳米线大面积光伏器件的技术优势与挑战

对于未来低成本、中等效率的太阳能电池装置来说，一个有前景的领域是使用蒸汽-液体-固体(VLS)生长的纳米线或微柱(NWs指的是两者)作为大规模(大于1mm2面积)光伏装置的有源区域。使用NWs有几个优点。NWs可以在生长过程中掺杂，有助于形成PV结构。与同样厚的平面吸收层相比，nw基PV结构需要更短的载流子扩散距离。同时，由于散射和其他光学现象，NW结构能够捕获更多的光，提高整体光吸收。这一点，再加上在廉价的衬底上生长纳米线或多次重复使用生长衬底的能力，使得NWs在未来一代光伏设备中很有前景。为了使核武器充分发挥其潜力，需要克服若干技术挑战。在本文中，我们将讨论这些技术挑战，并结合在大规模光伏设备中使用NWs的优势。我们还将概述我们和其他人在克服这些挑战的过程中取得的进展，使纳米线成为可行的光伏技术。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2010 35th IEEE Photovoltaic Specialists Conference

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