钙钛矿太阳能电池的Operando显微镜表征

C. Xiao, Changlei Wang, Chunsheng Jiang, Zhaoning Song, Yanfa Yan, M. Al‐Jassim
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引用次数: 0

摘要

在这项工作中,我们开发了operando开尔文探针力显微镜(KPFM)来研究光和正向偏置下钙钛矿电池的静电势分布,以深入了解器件的操作物理。作为案例研究,我们选择了具有SnO2基电子选择层(ESL)的钙钛矿电池,由于SnO2的传导带更深,电子迁移率更高,因此在制造高效率,无迟滞器件方面具有很大的潜力。该装置在钙钛矿/螺旋界面处有一个主结。在光浸泡和施加正向偏压后,结质量得到改善,可能是由于在界面处填充陷阱状态和钙钛矿吸收剂可能具有自极化效应;在ESL/钙钛矿界面处观察到主结。结果与电流-电压测量结果一致,器件性能的提高主要与填充因子的增强有关。在电流密度-电压测量或太阳能电池运行过程中,operando KPFM结果应更接近真实情况。我们所开发的operando KPFM技术可以为更深入地了解器件的运行机制和进一步优化器件提供有力的工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Operando Microscopy Characterization of Perovskite Solar Cells
In this work, we developed operando Kelvin probe force microscopy (KPFM) to study the electrostatic potential distribution across perovskite cells under light and forward bias to gain a deeper understanding of device operation physics. As a case study, we selected perovskite cells with a SnO2-based electron-selective layer (ESL), which showed great potential for fabricating high-efficiency, hysteresis-free devices due to the deeper conduction band and higher electron mobility of SnO2. The as-made device showed a main junction at the perovskite/spiro interface. After light soaking and applying forward bias, the junction quality improved, possibly explained by filling trap states at the interfaces and by the perovskite absorber perhaps having a self-poling effect; the main junction is observed at the ESL/perovskite interface. The results are consistent with current-voltage measurements, device performance improves mainly with fill factor enhancement. The operando KPFM results should more closely reflect the real case during current density-voltage measurements or solar cell operation. The operando KPFM technique that we have developed can be a powerful tool to provide a deeper understanding of the device operation mechanism and to further optimize the device.
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