材料科学
光电流
钙钛矿(结构)
磁滞
氧化铟锡
光电子学
离子键合
单层
钙钛矿太阳能电池
太阳能电池
半导体
氧化锡
电极
化学物理
氧化物
纳米技术
离子
能量转换效率
化学工程
薄膜
兴奋剂
凝聚态物理
物理化学
物理
工程类
量子力学
化学
冶金
作者
Yi Hou,Simon Scheiner,Xiaofeng Tang,Nicola Gasparini,Moses Richter,Ning Li,Peter Schweizer,Shi Chen,Haiwei Chen,César Omar Ramírez Quiroz,Xiaoyan Du,Gebhard J. Matt,Andres Osvet,Erdmann Spiecker,R. Fink,Andreas Hirsch,Marcus Halik,Christoph J. Brabec
标识
DOI:10.1002/admi.201700007
摘要
Thin‐film solar cell based on hybrid perovskites shows excellent light‐to‐power conversion efficiencies exceeding 22%. However, the mixed ionic‐electronic semiconductor hybrid perovskite exhibits many unusual properties such as slow photocurrent instabilities, hysteresis behavior, and low‐frequency giant capacitance, which still question us so far. This study presents a direct surface functionalization of transparent conductive oxide electrode with an ultrathin ≈2 nm thick phosphonic acid based mixed C60/organic self‐assembled monolayer (SAM) that significantly reduces hysteresis. Moreover, due to the strong phosphonates bonds with indium tin oxide (ITO) substrates, the SAM/ITO substrates also exhibit an excellent recyclability merit from the perspective of cost effectiveness. Impedance studies find the fingerprint of an ion‐based diffusion process in the millisecond to second regime for TiO 2 ‐based devices, which, however, is not observed for SAM‐based devices at these low frequencies. It is experimentally demonstrated that ion migration can be considerably suppressed by carefully engineering SAM interfaces, which allows effectively suppressing hysteresis and unstable diode behavior in the frequency regime between ≈1 and 100 Hz. It is suggested that a reduced density of ionic defects in combination with the absence of charge carrier accumulation at the interface is the main physical origin for the reduced hysteresis.
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