Role of exciton blocking layers as optical spacer in CuPc/C60 based organic solar cells

D. Datta, S. Sundar Kumar Iyer, Satyendra Kumar
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引用次数: 3

Abstract

The role of exciton blocking layer (EBL) in organic solar cells have been under intense investigation in the recent past. Although BCP (bathocuproine) has been commonly used as an EBL in CuPc/C60 based devices, its role as an effective optical spacer to increase the optical electric field intensity at the active layers, needs further investigation. In this work, using numerical techniques, we study the role of BCP as an optical spacer in CuPc/C60 based devices. For comparison, a higher refractive index material (TiOx; titanium suboxide) was also used. The optical constants of the BCP layer was extracted using spectroscopic ellipsometry using Tauc-Lorentz model dielectric function. The maximum device photocurrent density (Jsc-max) was simulated using transfer matrix formalism and exciton diffusion dynamics. The results with BCP as an optical spacer indicate that although a high gain in photocurrent can be obtained for devices with low active layer thicknesses, the enhancement in photocurrent from an already optimized device can at best be from 93.7 A/m2 to 98.7 A/m2, corresponding to a gain of only 5.3 %. Using a higher refractive index material such as TiOx, the current density for an already optimized device can at best be enhanced from 93.7 A/m2 to 97.5 A/m2, a gain of only 4 %. Overall, our results reveal that although the EBL acts as an optical spacer, the improvement in device absorption due to the optical effect is limited for an already optimized device. This indicates that the well known improvement in device performance by incorporating the buffer layer should be primarily related to other properties such as exciton blocking, electron transport, and avoiding acceptor damage during cathode deposition.
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激子阻挡层在CuPc/C60基有机太阳能电池中的光学间隔层作用
激子阻断层(EBL)在有机太阳能电池中的作用近年来得到了广泛的研究。虽然BCP (bathocuproine)在CuPc/C60基器件中通常用作EBL,但其作为有效的光间隔剂以增加有源层的光电场强度的作用还需要进一步研究。在这项工作中,我们使用数值技术研究了BCP作为光学间隔剂在基于CuPc/C60的器件中的作用。相比之下,一种更高折射率的材料(TiOx;也使用了亚氧化钛。利用陶克-洛伦兹模型介电函数,利用椭圆偏振光谱法提取了BCP层的光学常数。利用传递矩阵形式和激子扩散动力学模拟了器件最大光电流密度(Jsc-max)。以BCP作为光学间隔层的结果表明,虽然低有源层厚度的器件可以获得高光电流增益,但已经优化的器件的光电流增益最多可以从93.7 a /m2增加到98.7 a /m2,对应的增益仅为5.3%。使用更高折射率的材料,如TiOx,已经优化的器件的电流密度最多可以从93.7 a /m2提高到97.5 a /m2,增益仅为4%。总体而言,我们的研究结果表明,尽管EBL作为光学间隔器,但由于光学效应而导致的器件吸收的改善对于已经优化的器件是有限的。这表明,众所周知,通过加入缓冲层,器件性能的改善应该主要与其他特性有关,如激子阻断、电子传输,以及在阴极沉积过程中避免受体损伤。
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