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组合型光伏器件的量子效率和能带隙分析:全氧化物器件库中 Cu-O 化合物的分类活性。

Quantum efficiency and bandgap analysis for combinatorial photovoltaics: sorting activity of Cu-O compounds in all-oxide device libraries.

机构信息

Department of Chemistry, Center for Nanotechnology & Advanced Materials, Bar Ilan University , 52900 Ramat Gan, Israel.

出版信息

ACS Comb Sci. 2014 Feb 10;16(2):53-65. doi: 10.1021/co3001583. Epub 2014 Jan 10.

DOI:10.1021/co3001583
PMID:24410367
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4026971/
Abstract

All-oxide-based photovoltaics (PVs) encompass the potential for extremely low cost solar cells, provided they can obtain an order of magnitude improvement in their power conversion efficiencies. To achieve this goal, we perform a combinatorial materials study of metal oxide based light absorbers, charge transporters, junctions between them, and PV devices. Here we report the development of a combinatorial internal quantum efficiency (IQE) method. IQE measures the efficiency associated with the charge separation and collection processes, and thus is a proxy for PV activity of materials once placed into devices, discarding optical properties that cause uncontrolled light harvesting. The IQE is supported by high-throughput techniques for bandgap fitting, composition analysis, and thickness mapping, which are also crucial parameters for the combinatorial investigation cycle of photovoltaics. As a model system we use a library of 169 solar cells with a varying thickness of sprayed titanium dioxide (TiO2) as the window layer, and covarying thickness and composition of binary compounds of copper oxides (Cu-O) as the light absorber, fabricated by Pulsed Laser Deposition (PLD). The analysis on the combinatorial devices shows the correlation between compositions and bandgap, and their effect on PV activity within several device configurations. The analysis suggests that the presence of Cu4O3 plays a significant role in the PV activity of binary Cu-O compounds.

摘要

全氧化物基光伏器件(PVs)具有极低的成本潜力,前提是它们的功率转换效率能提高一个数量级。为了实现这一目标,我们对基于金属氧化物的光吸收体、电荷输运体、它们之间的结以及 PV 器件进行了组合材料研究。在这里,我们报告了一种组合内部量子效率(IQE)方法的开发。IQE 测量与电荷分离和收集过程相关的效率,因此是将材料放入器件后对 PV 活性的一种替代,摒弃了导致不受控制的光捕获的光学性质。IQE 得到了高通量技术的支持,这些技术用于带隙拟合、成分分析和厚度映射,这些技术对于光伏的组合研究循环也是至关重要的参数。作为一个模型系统,我们使用了一个由 169 个太阳能电池组成的库,这些电池的喷涂二氧化钛(TiO2)窗口层厚度不同,同时,通过脉冲激光沉积(PLD)制造的铜氧化物(Cu-O)二元化合物的厚度和成分也在变化。对组合器件的分析表明了组成和带隙之间的相关性,以及它们在几种器件配置中的对 PV 活性的影响。分析表明,Cu4O3 的存在在二元 Cu-O 化合物的 PV 活性中起着重要作用。

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