Ultra-thin ZnO film as an electron transport layer for realizing the high efficiency of organic solar cells
Author:
Affiliation:
1. Physics Department
2. Zhejiang Normal University
3. Zhejiang 321004
4. China
5. Key Laboratory of Semiconductor Materials Science
6. Institute of Semiconductors
7. Chinese Academy of Sciences
8. Beijing 100083
9. People's Republic of China
Abstract
We introduce an ultra-thin ZnO film (4 nm) into the PBDTTT-CF:PC70BM bulk-heterojunction organic solar cells as the electron transport layer and realize a power conversion efficiency of 7.51%.
Publisher
Royal Society of Chemistry (RSC)
Subject
General Chemical Engineering,General Chemistry
Link
http://pubs.rsc.org/en/content/articlepdf/2017/RA/C6RA27543E
Reference46 articles.
1. Fulleropyrrolidine interlayers: Tailoring electrodes to raise organic solar cell efficiency
2. All-brush-painted top-gate organic thin-film transistors
3. High-Efficiency, Low Turn-on Voltage Blue-Violet Quantum-Dot-Based Light-Emitting Diodes
4. Perovskite Solar Cells with 12.8% Efficiency by Using Conjugated Quinolizino Acridine Based Hole Transporting Material
5. Enhancement of solar cells parameters by periodic nanocylinders
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