通过高光谱时间分辨光致发光成像量化卤化物过磷酸盐中的重组和电荷载流子萃取

APL Energy Pub Date : 2024-03-01 DOI:10.1063/5.0188166
H. Phirke, S. Gharabeiki, A. Singh, A. Krishna, S. Siebentritt, A. Redinger
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引用次数: 0

摘要

确定卤化物包晶体太阳能电池中的非辐射重组源和量化电荷载流子萃取对于进一步开发这种薄膜技术非常重要。稳态和时间分辨光致发光 (TRPL) 与分析建模相结合,已成为实现预期结果的非破坏性工具。然而,在分析光致发光测量时,器件中重组和电荷载流子萃取损耗的确切位置往往被各种竞争过程所掩盖。在这里,我们通过绝对光子校准高光谱光致发光和 TRPL 成像展示了表面钝化和界面不均匀性如何影响光致发光量子产率和少数载流子寿命。通过从包晶石和玻璃/二氧化钛两侧进行激光照射,我们可以将表面重组速度的变化与电子传输层的电荷载流子萃取区分开来。我们发现,由于介孔(mp)-二氧化钛薄膜厚度的不均匀性,电荷萃取在空间上受到调制。我们的研究结果表明,介孔二氧化钛层并没有完全优化,因为电子特性在空间上发生了改变,导致准费米级分裂和少数载流子寿命发生横向变化,从而降低了开路电压。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantifying recombination and charge carrier extraction in halide perovskites via hyperspectral time-resolved photoluminescence imaging
Identifying sources of nonradiative recombination and quantifying charge carrier extraction in halide perovskite solar cells are important in further developing this thin-film technology. Steady-state and time-resolved photoluminescence (TRPL), in combination with analytical modeling, have emerged as non-destructive tools to achieve the desired results. However, the exact location of the recombination and charge carrier extraction losses in devices is often obscured by various competing processes when photoluminescence measurements are analyzed. Here, we show via absolute-photon-calibrated hyperspectral photoluminescence and TRPL imaging how surface passivation and inhomogeneities at interfaces impact the photoluminescence quantum yields and minority carrier lifetimes. Laser illumination from the perovskite and glass/TiO2 sides allows us to disentangle changes in surface recombination velocity from the charge carrier extraction at the electron transport layer. We find that charge extraction is spatially modulated due to an inhomogeneous mesoporous (mp)-TiO2 film thickness. Our results show that the mp-TiO2 layer is not fully optimized since the electronic properties are spatially modified, leading to lateral changes in quasi-Fermi-level splitting, minority carrier lifetime and, consequently, a reduction in open-circuit voltage.
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