P3HT
- 网络聚3-己基噻吩
P3HT-
Study of Organic Photocoupler Based on the Photovoltaic Characteristics of P3HT : PCBM
基于P3HT:PCBM光敏特性的光耦合器件的研究
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In this paper , we study the effects of silver nanoparticles on the performance of polymer solar cells based on P3HT : PCBM .
本文就是基于这一理论,在P3HT:PCBM体系的聚合物太阳能电池中,引入银纳米颗粒,研究其对聚合物太阳能电池性能的影响。
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However , from the AFM images of polymers , weather alkyl chain or resistance exist or not , it has no influence on the surface morphology of P3HT .
但由原子力显微镜的观察,异质界面层状材料中,P3HT的表面型态并不会有太大的差异;
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Finally , SWNTs are incorporated in an organic semiconducting polymer , poly ( 3-hexylthiophene ) ( P3HT ), to make a composite suspension .
最后,将单壁碳纳米管与有机半导体聚合物聚3-已基噻吩(P3HT)进行混合。
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By using acceptor with intense absorption in the visible spectrum , the solar spectrum response range of the former P3HT : PCBM device has been expanded from 650 nm to about 700 nm .
受体材料在可见光谱具有强烈的吸收,使得对于太阳光谱的响应范围已从P3HT:PCBM器件的650纳米扩大到700纳米左右。
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The maximum IPCE of titanate nanotubes / PMeT and titanate nanotubes / P3HT reached 11.40 % and 0.91 % respectively ( no correction for photon loss ) .
钛酸盐纳米管/PMeT、钛酸盐纳米管/P3HT的光电转换效率分别达11.40%,0.91%(未校正光子损失)。
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In this work , surface photovoltage technologies were chosen to study the photoelectric properties of organic P3HT : PCBM bulk heterojunctions , and the charge transport mechanisms of the heterojunctions were obtained from the surface photovoltage results .
本文中,就选取了表面光伏技术去研究P3HT:PCBM体异质结中的光电特性,通过光伏谱分析得到光生电荷的传输机制。
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To figure out the internal factors that limit organic / inorganic heterojunction solar cell efficiency , I selected the P3HT / n-Si heterojunction and analyzed the generation , separation and transport mechanism of the heterojunction using the surface photovoltage technology .
为弄清楚限制有机/无机异质结太阳能电池效率的内在因素,选取了P3HT/n-Si异质结结构,利用表面光伏技术分析了其中光生电荷的产生、分离和传输机制。
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Then , we used the ZnO nanoparticle film as the electron collection layer and fabricated the organic solar cell device . The structure of the device is ITO / ZnO / P3HT : PCBM / Ag . The best PCE of the device is 0.348 % .
利用纳米颗粒薄膜作为电子传输层,制备了结构为ITO/ZnO/P3HT:PCBM/Ag的太阳能电池器件,器件的最佳效率为0.348%。