Effect of the chemical composition of Cu–In–Ga–Se layers on the photoconductivity and conversion efficiency of CdS/CIGSe solar cells

被引:0
|
作者
G. F. Novikov
Wei-Tao Tsai
K. V. Bocharov
E. V. Rabenok
Ming-Jer Jeng
Liann-Be Chang
Wu-Shiung Feng
Jian-Ping Ao
Yun Sun
机构
[1] Russian Academy of Sciences,Institute of Problems of Chemical Physics
[2] Chang Gung University,Department of Electronic Engineering
[3] Nankai University,Institute of Photoelectronic Thin Film Device and Technology
来源
Semiconductors | 2016年 / 50卷
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摘要
The effect of the [Ga]/[In+Ga] ratio of gallium and indium on the microwave photoconductivity of Cu–In–Ga–Se (CIGSe) films and on the efficiency of solar cells fabricated in accordance with the same technology is investigated. According to the observations of a field-emission scanning electron microscopy (FESEM), the grain size decreases with increasing Ga content. With increasing gallium content in the samples, the photogenerated-electron lifetime and the activation energy of the microwave photoconductivity also decrease. The changes in the activation energy of the through conduction in darkness are less than 20%. Analysis of the obtained data shows that the known effect of the gallium gradient on the efficiency should be associated with modification of the internal structure of grains instead of with their boundaries.
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页码:1344 / 1351
页数:7
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