通过等离子体增强荧光提高聚合物在环境氧中的光稳定性

Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX Pub Date : 2021-08-02 DOI:10.1117/12.2594762

S. Goldberg, L. Peteanu

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引用次数: 0

摘要

有机半导体是开发光电器件的常用材料。然而，这些材料在光和氧的存在下会迅速降解。我们扩展了以前使用金属薄膜的方法，通过金属增强荧光来增强聚合物的稳定性。当聚合物的等离子体峰和荧光峰重叠时，辐射衰减率增加。等离子体可以通过改变镀膜用溅射镀膜机的沉积时间和电流设置来调谐。通过获得沉积在金属薄膜上的聚合物的荧光图像，与在环境空气中的玻璃上的聚合物相比，通过等离子体相互作用发现了高度的稳定性。我们还获得了聚合物在玻璃、电子传输层和金膜上的寿命，以比较等离子体相互作用和电荷转移对寿命的影响。用这种方法探讨了等离子体在有机太阳能电池材料中的应用。

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The increased photostability of polymers in ambient oxygen via plasmonic enhanced fluorescence

Organic semiconductors are commonly used for the development optoelectronic devices. However, these materials degrade rapidly in the presence of light and oxygen. we expand upon our previously methods of using thin metal films to enhance the stability of a polymer via metal enhanced fluorescence. When overlap of the plasmon peak and peak fluorescence of the polymer is achieved the radiative decay rate increases. The plasmon can be tuned via changing the deposition time and current settings of the sputter coater used for coating. By obtaining fluorescence images of the polymer deposited on the metal film compare to on glass in ambient air, a high degree of stabilization is found via plasmonic interactions. Lifetimes were also obtained of the polymer on glass, an electron transporting layer, and a gold film to compare the changes in lifetime from plasmonic interactions versus charge transfer. The usefulness of plasmonic for organic solar cell materials was probed in this way.

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Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX

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