Theoretical Prediction on Photovoltaic Properties of 4Cl-BPPQ/PC61BM System via Density Functional Theory Calculations
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- 作者:Caibin Zhao ; Qiang Zhang ; Ke Zhou ; Hongguang Ge ; Wenliang Wang and Shiwei Yin
- 刊名:Chinese Journal of Chemistry
- 出版年:2016
- 出版时间:November, 2016
- 年:2016
- 卷:34
- 期:11
- 页码:1143-1150
- 全文大小:542K
- ISSN:1614-7065
文摘
Designing and synthesizing high-performable electron donor materials are very important for fabricating organic solar cell devices with high power conversion efficiency (PCE). In this work, quantum chemical and molecular dynamics calculations coupled with the Marcus-Hush charge transfer model were used to investigate the photovoltaic properties of 4Cl-BPPQ/PC61BM. Results reveal that 4Cl-BPPQ/PC61BM system theoretically possesses a large open-circuit voltage (1.29 V), high fill factor (0.90), and over 9% PCE. Moreover, calculations also reveal that the 4Cl-BPPQ/PC61BM system has a middle-sized exciton binding energy (0.492 eV), but relatively small charge-dissociation and charge-recombination reorganization energies (0.345 eV and 0.355 eV). Based on the 4Cl-BPPQ/PC61BM complex, the charge-dissociation rate constant, kdis, is estimated to be as large as 6.575×1012 s−1, while the charge-recombination one, krec, is very small (<1.0 s−1) under the same condition due to the very small driving force (ΔGrec=−1.900 eV). In addition, by means of an amorphous cell containing one hundred 4Cl-BPPQ molecules, the hole carrier mobility of 4Cl-BPPQ solid is estimated as high as 3.191×10−3 cm2·V−1·s−1. In brief, our calculation shows that 4Cl-BPPQ/PC61BM system is a very promising organic solar cell system, and is worth of making further device research by experiments.