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光伏发电技术
★ 5.0
通过优化界面工程提升PbS-I量子点太阳能电池的电荷提取效率
Enhancing charge extraction efficiency in PbS-I quantum dot solar cell through optimized interface engineering
| 作者 | Muhammad Zahir Iqbal · Atika Bibi · Sajid Khan · Subhash Chandr · Abhinav Kumar · Sumit Kaushal · Vijayalaxmi Mishr · Yusuf Siraj Usmani |
| 期刊 | Solar Energy |
| 出版日期 | 2025年1月 |
| 卷/期 | 第 287 卷 |
| 技术分类 | 光伏发电技术 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | Synthesis of PbS-I-QDs by hot injection method. |
语言:
中文摘要
摘要 碘配体封端的硫化铅胶体量子点(PbS-I-CQDs)在下一代光伏器件中具有重要应用前景。然而,其性能受到吸收层内部及界面处非辐射载流子复合与电荷积累的限制。本文采用界面异质结策略,在吸收层(PbS-I)与载流子收集电极(Au)之间引入乙二硫醇封装的硫化铅(PbS-EDT)量子点薄膜作为空穴传输层(HTL),以缓解上述问题。为研究PbS-I-CQDs的光伏性能,我们设计了两种不同的器件结构:无HTL结构(Glass\ITO\ZnO\PbS-I\Au)和含HTL结构(Glass\ITO\ZnO\PbS-I\PbS-EDT\Au)。结果表明,引入PbS-EDT后,器件的光电转换效率(PCE)显著提升至10.7%,证明PbS-EDT是适用于PbS-I-CQDs基太阳能电池的最适配HTL材料。PbS-EDT通过抑制非辐射复合和减少电荷积累,有效提高了载流子迁移率。本研究旨在为基于PbS-I-CQDs的太阳能电池寻找理想的空穴传输层,以提升其光伏性能。
English Abstract
Abstract Iodine capped lead sulfide colloidal quantum dots (PbS-I-CQDs) offer significant potential for next generation photovoltaics. However, the performance is hampered by nonradiative carriers’ recombination and charge accumulation within the absorbing layer and at interfaces. Here, we employed an interface heterojunction approach by incorporating thin film of ethanedithiol encapsulated lead sulfide (PbS-EDT) quantum dots as HTL between absorbing layer (PbS-I) and carrier collector (Au) to mitigate the challenges. To investigate the photovoltaic performance of PbS-I-CQDs we designed two different device architectures i.e., HTL free (Glass\ITO\ZnO\PbS-I\Au) and HTL incorporated (Glass\ITO\ZnO\PbS-I\PbS-EDT\Au). The results highlight that PCE is significantly enhanced by up to 10.7%, demonstrating that PbS-EDT is most compatible HTL for PbS-I-CQDs based solar cells. PbS-EDT enhances the carrier mobility by minimizing nonradiative carrier recombination and accumulation. The purpose of this study is to search for an ideal HTL for PbS-I-CQDs based solar cells to enhance their photovoltaic performance.
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SunView 深度解读
该PbS量子点太阳能电池界面工程优化技术对阳光电源SG系列光伏逆变器具有前瞻参考价值。研究通过PbS-EDT空穴传输层优化载流子提取,将光电转换效率提升至10.7%,其界面异质结设计理念可启发我们在MPPT算法中针对新型光伏材料优化追踪策略。该技术降低非辐射复合、提升载流子迁移率的思路,与我们三电平拓扑中减少开关损耗、优化功率器件界面设计的目标一致,为未来支持量子点等新型光伏技术的逆变器研发提供界面工程优化方向。