Clean interface without any intermixed state between ultra-thin P3 polymer and CH3NH3PbI3 hybrid perovskite thin film

Min-Cherl Jung; Asuka Matsuyama; Sora Kobori; Inhee Maeng; Young Mi Lee; Myungkwan Song; Sung-Ho Jin; Masakazu Nakamura

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Clean interface without any intermixed state between ultra-thin P3 polymer and CH3NH3PbI3 hybrid perovskite thin film

机译：无需超薄P3聚合物和CH3NH3PBI3杂交钙钛矿薄膜之间的清洁界面而没有任何混合状态

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Hole transport layers (HTL) are crucial materials to improve the power conversion efficiency in organohalide hybrid perovskite-based solar-cell applications. Two important physical properties are required in HTL materials: good hole mobility and air-protection. After HTL solution-based deposition, an intermixed chemical state at the interface between HTL and hybrid perovskite is key to confirming the physical property of HTL. We performed high-resolution x-ray photoelectron spectroscopy to investigate the chemical states at the interface between an ultra-thin P3 polymer and CHsub3/subNHsub3/subPbIsub3/sub hybrid perovskite thin film. At the interface, we found no apparent intermixed chemical state. Furthermore, we confirmed that the P3 HTL with the ultra-thin layer (7?nm) protected the hybrid perovskite material against air-exposure for 2 weeks.

机译：空穴传输层（HTL）是关键材料，以提高有机卤化物杂交钙耐钙耐矿的太阳能电池应用中的功率转换效率。 HTL材料需要两个重要的物理性质：良好的孔移动和空气保护。在基于HTL溶液的沉积之后，HTL和杂交钙钛矿之间的界面处的混合化学状态是确认HTL的物理性质的关键。我们进行了高分辨率X射线光电子能谱，以研究超薄P3聚合物和CH _{3 / sup> 3 Pbi _{3 pbi _{3 < /亚>杂交钙钛矿薄膜。在界面处，我们发现没有明显的混合化学状态。此外，我们证实，具有超薄层（7Ω·NM）的P3 HTL保护杂交钙钛矿材料免受空气暴露2周的影响。}}}

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《Scientific reports.》 |2019年第1期|共页
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Min-Cherl Jung; Asuka Matsuyama; Sora Kobori; Inhee Maeng; Young Mi Lee; Myungkwan Song; Sung-Ho Jin; Masakazu Nakamura;
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1. Antisolvent-assisted powder engineering for controlled growth of hybrid CH3NH3PbI3 perovskite thin films [J] . Yong Chan Choi, Se Won Lee, Dae-Hwan Kim APL Materials . 2017,第2期

机译：反溶剂辅助粉末工程可控制杂化CH3NH3PbI3钙钛矿薄膜的生长
2. Mapping the Photoresponse of CH3NH3PbI3 Hybrid Perovskite Thin Films at the Nanoscale [J] . Kutes Yasemin, Zhou Yuanyuan, Bosse James L., Nano letters . 2016,第6期

机译：在纳米尺度上绘制CH3NH3PbI3杂化钙钛矿薄膜的光响应
3. Controlled growth of organic-inorganic hybrid CH3NH3PbI3 perovskite thin films from phase-controlled crystalline powders [J] . Choi Yong Chan, Lee Se Won, Jo Hyo Jeong, RSC Advances . 2016,第106期

机译：来自相控制结晶粉末的有机 - 无机杂交CH3NH3PB13钙钛矿薄膜的受控生长
4. ROLE OF THE FABRICATION TECHNIQUE IN THE STABILITY OF CH3NH3PBI3 PEROVSKITE THIN FILMS [C] . Mehran Habibi, Morteza Eslamian European Photovoltaic Solar Energy Conference and Exhibition . 2017

机译：制造技术在CH3NH3PB13钙钛矿薄膜稳定性中的作用
5. Investigations of Hybrid Perovskite Thin Films and Interfacing TiO2 Electrode Surfaces: Chemical Origins of Nanoscale Structural and Electrical Properties for Photovoltaic Applications [D] . Stanfill, James. 2020

机译：Hybrid Perovskite薄膜和接口TiO2电极表面的研究：光伏应用的纳米级结构和电性能的化学渊源
6. Clean interface without any intermixed state between ultra-thin P3 polymer and CH3NH3PbI3 hybrid perovskite thin film [O] . Min-Cherl Jung, Asuka Matsuyama, Sora Kobori, -1

机译：超薄P3聚合物与CH3NH3PbI3混合钙钛矿薄膜之间无任何混杂状态的清洁界面
7. Clean interface without any intermixed state between ultra-thin P3 polymer and CH3NH3PbI3 hybrid perovskite thin film [O] . Min-Cherl Jung, Asuka Matsuyama, Sora Kobori, 2019

机译：无需超薄P3聚合物和CH3NH3PBI3杂交钙钛矿薄膜之间的清洁界面而没有任何混合状态

Clean interface without any intermixed state between ultra-thin P3 polymer and CH3NH3PbI3 hybrid perovskite thin film

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