Material Perspective for Hole Transport Material-Free Perovskite Solar Cell: A Mini Review

S. S. Nisa, T. Paramitha, H. Aliwarga, H. Widiyandari, Agus Supriyanto, Rista Tristanti Kisdina, Rifdha Hendianti Kisdina, Nanda Yudi Shofi Subekti, Marcus Saputra
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Abstract

The technology for converting energy from sunlight (photovoltaic) has entered the third generation. The Perovskite Solar Cell (PSC) can compete with the efficiency of current silicon solar cells. However, from the commercial side, there are still obstacles due to the high price of the hole transport material. This component prevents electrons from being transferred to the anode. It also extracts and transports active layer holes to the electrode. This material can be removed since perovskite material can play a dual role. Perovskite materials can be utilized as light harvesters and hole conductors. However, the absence of one component in the PSC structure certainly affects PSC performance. Therefore, in this review, several developments of hole-transport material-free PSC are discussed regarding the type of material used. It starts from the electron transport layer, perovskite layer, and counter electrode. The TiO2 material is most often used for the electron transport layer because it can achieve a power conversion efficiency (PCE) of >12%. Moreover, with the addition of doping, the PCE value can reach 14.06%. In addition, for the perovskite layer, with a slight modification of the MAPbI3 material, the PCE value is >16%.
无空穴传输材料的透镜太阳能电池的材料视角:微型综述
从太阳光中转换能量(光伏)的技术已进入第三代。Perovskite 太阳能电池(PSC)的效率可与目前的硅太阳能电池相媲美。然而,在商业方面,由于空穴传输材料的高昂价格,仍然存在障碍。这种材料可以防止电子转移到阳极。它还能提取活性层空穴并将其传输到电极。这种材料可以去除,因为过氧化物材料可以发挥双重作用。透镜材料可用作光收集器和空穴导体。然而,PSC 结构中缺少一种成分肯定会影响 PSC 的性能。因此,本综述就所用材料的类型讨论了无空穴传输材料 PSC 的几种发展情况。本文从电子传输层、过氧化物层和对电极入手。电子传输层最常用的是二氧化钛材料,因为它的功率转换效率(PCE)大于 12%。此外,在添加掺杂剂后,PCE 值可达到 14.06%。此外,对于过氧化物层,只要对 MAPbI3 材料稍加改良,其 PCE 值就能大于 16%。
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