单壁碳纳米管在提高P3HT:PCBM太阳能电池效率中的作用-阻抗光谱和形态学研究

A. T. Mallajosyula, S. Sundar Kumar Iyer, B. Mazhari
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引用次数: 4

摘要

制备了掺杂SWNTs的P3HT:PCBM体异质结(BHJ)太阳能电池,其效率比未掺杂器件提高了一倍。在制造过程中没有对单壁碳纳米管进行表面修饰。吸收光谱和光致发光光谱以及器件的光电流和光谱响应表明,SWNTs在P3HT:SWNT界面上没有产生任何显着的电荷,这表明s-SWNTs与P3HT之间可能的ii型异质结主要是由金属管引起的影响。在0.75 wt%的最佳swnt浓度下,观察到有效迁移率提高了10%。在太阳能电池工作的电压范围内,注入电流密度增加了两个数量级,并具有欧姆特性。从电容电压特性的峰值电压可以推断,单壁碳纳米管使器件的Vbi仅降低了60 mV。从扩散输运模式的Cole-Cole模型可以观察到,注入的载流子寿命从0.628 ms降低到0.125 ms。在低频的单壁碳纳米管器件中,反向偏置的负电容与正向偏置的负电容具有相似的电场依赖性。这是由于通过SWNT能级注入的大反向电流,使得空间电荷、捕获和重组的影响显著。表面粗糙度和体积增加了一倍以上,导致阴极覆盖面积增加,影响电荷收集效率。利用归一化到暗电流的光电流损耗来分析电荷提取效率,其中使用单壁纳米管可以观察到两个数量级的提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Role of single walled carbon nanotubes in improving the efficiency of P3HT:PCBM solar cells - impedance spectroscopy and morphology studies
Bulk heterojunction (BHJ) solar cells of P3HT:PCBM doped with SWNTs were fabricated which doubled the efficiency over the undoped devices. No surface modifications of SWNTs were done during fabrication. Absorption and photoluminescence spectra along with photocurrent and spectral response of the devices show that SWNTs do not result in any significant charge generation at the P3HT:SWNT interface indicating that possible type-II heterojunctions between s-SWNTs and P3HT were dominated by the effects due to metallic tubes. At an optimum concentration of 0.75 wt% SWNTs, a 10% improvement in effective mobility was observed. In the voltage range of solar cell operation, two orders increase in injected current density is observed which has an Ohmic behavior. From the peak voltage of the capacitance-voltage characteristics, it was inferred that SWNTs reduce the Vbi of the devices by only 60 mV. From the Cole-Cole in the diffusion transport regime, it was observed that the injected carrier life time gets lowered from 0.628 ms to 0.125 ms with SWNTs. A negative capacitance was observed in reverse bias in devices with SWNTs at low frequencies which has similar dependence on applied field as that in forward bias. This is attributed to the large reverse current injected through SWNT energy levels, making the effects of space charge, trapping, and recombination significant. The surface roughness and volume were more than doubled with SWNTs which resulted in increased cathode coverage area affecting the charge collection efficiency. Charge extraction efficiency is analyzed using the photocurrent loss normalized to the dark current where two orders of magnitude improvement is observed with SWNTs.
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