Assessment of off-axis and in-line electron holography for measurement of potential variations in Cu(In,Ga)Se2 thin-film solar cells

IF 3.56 Q1 Medicine
Debora Keller, Stephan Buecheler, Patrick Reinhard, Fabian Pianezzi, Etienne Snoeck, Christophe Gatel, Marta D. Rossell, Rolf Erni, Ayodhya N. Tiwari
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引用次数: 7

Abstract

Electron holography is employed to study variations of the electrostatic crystal potential in Cu(In,Ga)Se2 (CIGS) thin-film solar cells at different length scales: Long-range potential variations across the layer structure of the solar cell as well as inhomogeneities within the layers are analyzed by off-axis holography. In-line holography is applied to examine the local potential variation across a CIGS grain boundary. The phase reconstruction from a focal series is performed by a modified transport of intensity equation (TIE) which is optimized to reduce common artifacts. For comparison, three different microscopes of different optical configurations were used for in-line holography. Based on the results, the impact of the used microscope as well as further acquisition parameters on the in-line holography measurement is assessed. The measured potential variations are discussed considering the effect of different possible sources that may cause potential fluctuations. It is found that most of the variations are best explained by mean inner potential fluctuations rather than by inhomogeneities of the electronic properties. Finally, the present resolution limit of both methods is discussed regarding the feasibility of future electronic characterization of CIGS by holography.

Abstract Image

离轴和直线电子全息测量Cu(in,Ga)Se2薄膜太阳能电池电位变化的评估
利用电子全息技术研究了Cu(in,Ga)Se2 (CIGS)薄膜太阳能电池在不同长度尺度下静电晶体电位的变化,利用离轴全息技术分析了太阳能电池层间结构的长程电位变化以及层内的不均匀性。采用直线全息技术研究了CIGS晶界上的局部电位变化。通过改进的强度传递方程(TIE)进行了相位重建,该方程经过优化以减少常见伪影。为了比较,我们使用了三种不同光学结构的显微镜进行了在线全息摄影。在此基础上,评估了所使用的显微镜以及其他采集参数对在线全息测量的影响。考虑到可能引起电位波动的不同可能源的影响,讨论了测量的电位变化。发现大多数的变化最好的解释是平均内势波动,而不是电子性质的不均匀性。最后,讨论了两种方法目前的分辨率限制,以及未来用全息技术对CIGS进行电子表征的可行性。
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来源期刊
Advanced Structural and Chemical Imaging
Advanced Structural and Chemical Imaging Medicine-Radiology, Nuclear Medicine and Imaging
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