Thin Film Materials Laboratory, Department of Physics, Shivaji University, Kolhapur, 416004, India.
School of Materials Science and Innovation, Faculty of Science, Mahidol University, Bangkok, Thailand.
ChemSusChem. 2019 Nov 8;12(21):4724-4753. doi: 10.1002/cssc.201901505. Epub 2019 Oct 14.
Quantum dot solar cells (QDSCs) are attractive technology for commercialization, owing to various advantages, such as cost effectiveness, and require relatively simple device fabrication processes. The properties of semiconductor quantum dots (QDs), such as band gap energy, optical absorption, and carrier transport, can be effectively tuned by modulating their size and shape. Two types of architectures of QDSCs have been developed: 1) photoelectric cells (PECs) fabricated from QDs sensitized on nanostructured TiO , and 2) photovoltaic cells fabricated from a Schottky junction and heterojunction. Different types of semiconductor QDs, such as a secondary, ternary, quaternary, and perovskite semiconductors, are used for the advancement of QDSCs. The major challenge in QDSCs is the presence of defects in QDs, which lead to recombination reactions and thereby limit the overall performance of the device. To tackle this problem, several strategies, such as the implementation of a passivation layer over the QD layer and the preparation of core-shell structures, have been developed. This review covers aspects of QDSCs that are essential to understand for further improvement in this field and their commercialization.
量子点太阳能电池(QDSCs)由于成本效益高,且相对简单的器件制造工艺等优点,成为一种有吸引力的商业化技术。半导体量子点(QDs)的性质,如能带隙能量、光学吸收和载流子输运,可以通过调节其尺寸和形状来有效调整。QDSCs 已经开发出两种结构类型:1)在纳米结构 TiO 上敏化的量子点制成的光电电池(PECs),和 2)由肖特基结和异质结制成的光伏电池。不同类型的半导体 QDs,如二次、三元、四元、钙钛矿半导体,被用于推进 QDSCs 的发展。QDSCs 的主要挑战在于 QDs 中存在缺陷,这导致了复合反应,从而限制了器件的整体性能。为了解决这个问题,已经开发了几种策略,例如在 QD 层上实施钝化层和制备核壳结构。这篇综述涵盖了理解 QDSCs 的重要方面,以便进一步改进该领域并实现其商业化。
