Solution‐Processed PEDOT:PSS/p‐Si/ZnO Heterojunction Solar Cells

physica status solidi (RRL) – Rapid Research Letters Pub Date : 2023-07-04 DOI:10.1002/pssr.202300168

Wenzheng Jiang, Yu Wang, Chaohui Jiao, Yang Wang, Yonggang Zhao, Mingzhi Lv, Zining Fan, Yujun Fu, Junshuai Li, Qiming Liu, D. He

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Abstract

With the introduction of the concept of dopant‐free carrier‐selective contact for c‐Si photovoltaics, Si‐based heterojunction solar cells can greatly reduce production costs by optimizing the manufacturing process while maintaining high power conversion efficiency. Compared with processes that rely on complex vacuum equipment, low‐temperature solution processing has many advantages over conventional silicon solar cells. However, research on low‐cost and high‐efficiency solar cells based on p‐type crystalline silicon is relatively rare. From the point of view regards energy band matching, the inorganic metal oxide semiconductor material ZnO is well suited for low‐cost solution method studies due to its easy preparation, very high transmittance in the visible spectrum, low cost, and suitable energy levels matching p‐Si. Herein, ZnO is spin coated on the back of p‐Si to form a heterojunction, together with spin coating of PEDOT:PSS on the front side as the hole transport layer and passivation layer, a PEDOT:PSS/p‐Si/ZnO‐structured p‐Si‐based backcontact hybrid solar cell is successfully fabricated at low temperature (≤135 °C) via solution process with a PCE of 9.77% (Voc = 0.56 V, Jsc = 25.99 mA cm−2, fill factor = 67.10%). This work provides a promising approach for fabricating high‐performance and low‐cost silicon‐based heterojunction solar cells.

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溶液处理的PEDOT:PSS/p‐Si/ZnO异质结太阳能电池

随着硅基异质结太阳能电池无掺杂载流子选择性接触概念的引入，硅基异质结太阳能电池可以通过优化制造工艺大大降低生产成本，同时保持高功率转换效率。与依赖于复杂真空设备的工艺相比，低温溶液工艺比传统的硅太阳能电池具有许多优势。然而，基于p型晶体硅的低成本、高效率太阳能电池的研究相对较少。从能带匹配的角度来看，无机金属氧化物半导体材料ZnO由于其制备简单、可见光谱透射率高、成本低、适合与p - Si匹配的能级，非常适合低成本溶液法研究。在p‐Si背面自旋涂覆ZnO形成异质结，在p‐Si背面自旋涂覆PEDOT:PSS作为空穴输运层和钝化层，在低温(≤135℃)下通过溶液法制备了PCE为9.77% (Voc = 0.56 V, Jsc = 25.99 mA cm−2，填充系数= 67.10%)的PEDOT:PSS/p‐Si/ZnO结构p‐Si基后接触杂化太阳能电池。这项工作为制造高性能和低成本的硅基异质结太阳能电池提供了一种有前途的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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physica status solidi (RRL) – Rapid Research Letters

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