Revealing the origins of open circuit voltage loss in perovskite solar cells by surface photovoltage measurement (Conference Presentation)

Ji‐Seon Kim
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Abstract

Continuous increase in the device performance of lead halide perovskite-based solar cells is strongly related to better understanding of the optoelectronic processes occurring in the perovskite layer and its interfaces. There are many of these processes that are critical to device performance, but are not yet fully understood, which include charge carrier accumulation and recombination, trapping of electrons and holes, and ionic movement. Here we report our recent results of methylammonium lead iodide (MAPI)-based photovoltaic devices identifying the origins of different open circuit voltages and their potential loss mechanisms in conventional and inverted device structures. We have investigated in detail the energetics and the illumination generated surface photovoltage (SPV) and its transient behaviour at the perovskite layer and its heterointerfaces with various charge extracting interlayers. A MAPI layer with different thicknesses was deposited on top of the various underlayers including ITO, n-type TiO2, p-type PEDOT:PSS and many oxides and organic semiconductors. We found that the work function of MAPI is strongly influenced by the underlayer showing generally p-type semiconductor character. The results of thickness dependent SPV measurements indicate that there is an increase in the hole concentration at both PEDOT:PSS/MAPI and TiO2/MAPI interfaces, which leads to an increased interfacial charge recombination. In this talk, I will discuss how these observations are related to different open circuit voltages and their loss in conventional and inverted devices. I will also discuss the temperature dependent transient SPV results, which is used to distinguish different processes governed by charge carrier generation, ion migration, and charge trapping – three processes taking place at three different timescales.
通过表面光电压测量揭示钙钛矿太阳能电池开路电压损失的根源(会议报告)
卤化铅钙钛矿基太阳能电池器件性能的持续提高与更好地理解钙钛矿层及其界面中发生的光电过程密切相关。这些过程中有许多对器件性能至关重要,但尚未完全理解,包括电荷载流子的积累和重组,电子和空穴的捕获以及离子运动。在此,我们报告了基于甲基碘化铅(MAPI)的光伏器件的最新研究结果,确定了不同开路电压的来源及其在传统和倒置器件结构中的潜在损耗机制。我们详细地研究了钙钛矿层及其异质界面上的能量学和表面光电压(SPV)及其瞬态行为。在ITO、n型TiO2、p型PEDOT:PSS以及多种氧化物和有机半导体等底层材料上沉积了不同厚度的MAPI层。我们发现MAPI的功函数受到底层的强烈影响,表现出普遍的p型半导体特性。厚度相关的SPV测量结果表明,PEDOT:PSS/MAPI和TiO2/MAPI界面上的空穴浓度增加,导致界面电荷复合增加。在这次演讲中,我将讨论这些观察结果如何与传统和反向器件中的不同开路电压及其损耗相关。我还将讨论温度相关的瞬态SPV结果,该结果用于区分由载流子产生、离子迁移和电荷捕获控制的不同过程,这三个过程发生在三个不同的时间尺度上。
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