Application of a NADH-modified ZnO electron transport layer in high performance organic solar cells†

IF 5.7 2区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Materials Chemistry C Pub Date : 2024-09-28 DOI:10.1039/D4TC03144J

Hongye Li, Song Yang and Huangzhong Yu

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Abstract

As an electron transport layer (ETL) widely used in organic solar cells (OSCs), ZnO has issues with energy level mismatch with the active layer and excessive surface defects, which ultimately reduce the efficiency of OSCs. Here, a ZnO:NADH ETL is prepared by modifying ZnO with green biomaterial nicotinamide adenine dinucleotide (NADH). XPS and UPS show that ZnO obtains electrons from NADH and decreases the work function of ZnO, thus lowering the interface barrier between ZnO and the active layer, which is conducive to electron collection in OSCs. At the same time, the oxygen vacancy density on the ZnO surface reduces after modification with biomaterial NADH, thus improving the electrical conductivity of ZnO. Finally, we use PM6:Y6 and PM6:L8-BO as active layers, and use ZnO:NADH as a novel ETL in OSCs, achieving efficiencies of 16.77% and 18.21%, respectively. The stability of the device with the ZnO:NADH ETL has also been improved to a certain extent. This study provides an effective method for ZnO modification, and also contributes to the environmental protection in the device preparation process.

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NADH 改性氧化锌电子传输层在高性能有机太阳能电池中的应用†.

作为一种广泛应用于有机太阳能电池（OSCs）的电子传输层（ETL），氧化锌存在与活性层能级不匹配和表面缺陷过多的问题，最终降低了 OSCs 的效率。本文通过用绿色生物材料烟酰胺腺嘌呤二核苷酸（NADH）修饰氧化锌，制备了 ZnO:NADH ETL。XPS 和 UPS 显示，氧化锌从 NADH 中获得电子，降低了氧化锌的功函数，从而降低了氧化锌与活性层之间的界面势垒，有利于 OSC 中的电子收集。同时，用生物材料 NADH 修饰后，氧化锌表面的氧空位密度降低，从而提高了氧化锌的导电性。最后，我们使用 PM6:Y6 和 PM6:L8-BO 作为活性层，并使用 ZnO:NADH 作为新型 ETL，在 OSC 中分别实现了 16.77% 和 18.21% 的效率。使用 ZnO:NADH ETL 的器件的稳定性也得到了一定程度的提高。这项研究为氧化锌改性提供了一种有效的方法，同时也为器件制备过程中的环境保护做出了贡献。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Materials Chemistry C MATERIALS SCIENCE, MULTIDISCIPLINARY-PHYSICS, APPLIED

CiteScore

10.80

自引率

6.20%

发文量

1468

期刊介绍： The Journal of Materials Chemistry is divided into three distinct sections, A, B, and C, each catering to specific applications of the materials under study: Journal of Materials Chemistry A focuses primarily on materials intended for applications in energy and sustainability. Journal of Materials Chemistry B specializes in materials designed for applications in biology and medicine. Journal of Materials Chemistry C is dedicated to materials suitable for applications in optical, magnetic, and electronic devices. Example topic areas within the scope of Journal of Materials Chemistry C are listed below. This list is neither exhaustive nor exclusive. Bioelectronics Conductors Detectors Dielectrics Displays Ferroelectrics Lasers LEDs Lighting Liquid crystals Memory Metamaterials Multiferroics Photonics Photovoltaics Semiconductors Sensors Single molecule conductors Spintronics Superconductors Thermoelectrics Topological insulators Transistors