Molecular engineering of contact interfaces for high-performance perovskite solar cells

IF 79.8 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nature Reviews Materials Pub Date : 2022-11-04 DOI:10.1038/s41578-022-00503-3

Furkan H. Isikgor, Shynggys Zhumagali, Luis V. T. Merino, Michele De Bastiani, Iain McCulloch, Stefaan De Wolf

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引用次数: 51

Abstract

Metal-oxide-based charge-transport layers have played a pivotal role in the progress of perovskite solar cells. Yet metal-oxide/perovskite interfaces are often highly defective, owing to both metal-oxide and perovskite surface defects. This results in non-radiative recombination and impedes charge transfer. Moreover, during operation, such interfaces may suffer from undesirable chemical reactions and mechanical delamination issues. Solving this multifaceted challenge requires a holistic approach to concurrently address the interfacial defect, charge-transfer, chemical stability and delamination issues, to bring perovskite solar cell technology closer to commercialization. With this motivation, we review and discuss the issues associated with the metal-oxide/perovskite interface in detail. With this knowledge at hand, we then suggest solutions based on molecular engineering for many, if not all, challenges that encumber the metal-oxide/perovskite interface. Specifically, in light of the semiconducting and ultrafast charge-transfer properties of dyes and the recent success of self-assembled monolayers as charge-selective contacts, we discuss how such molecules can potentially be a promising solution for all metal-oxide/perovskite interface issues. In perovskite solar cells, metal-oxide/perovskite interfaces suffer from a combination of issues related to interfacial defects, charge transfer, chemical stability and delamination, limiting performance. This Review discusses how molecular engineering of metal-oxide/perovskite interfaces with self-assembled monolayers can provide a solution and help to bring perovskite solar cells to market.

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高性能钙钛矿太阳能电池接触界面的分子工程

基于金属氧化物的电荷传输层在过氧化物太阳能电池的发展过程中起到了举足轻重的作用。然而，由于金属氧化物和包晶表面缺陷的存在，金属氧化物/包晶界面往往存在严重缺陷。这会导致非辐射性重组，阻碍电荷转移。此外，在运行过程中，这些界面可能会发生不良的化学反应和机械分层问题。要解决这一多方面的挑战，就必须采用整体方法，同时解决界面缺陷、电荷转移、化学稳定性和分层问题，从而使包晶石太阳能电池技术更接近商业化。基于这一动机，我们将详细回顾和讨论与金属氧化物/包晶石界面相关的问题。有了这些知识，我们就可以提出基于分子工程的解决方案，以解决困扰金属氧化物/透镜石界面的许多（如果不是全部）难题。具体来说，考虑到染料的半导体和超快电荷转移特性，以及最近自组装单层作为电荷选择性接触的成功，我们讨论了此类分子如何有可能成为解决所有金属氧化物/过氧化物界面问题的一种有前途的解决方案。在过氧化物太阳能电池中，金属氧化物/过氧化物界面存在界面缺陷、电荷转移、化学稳定性和分层等一系列问题，从而限制了其性能。本综述将讨论如何利用自组装单层对金属氧化物/透闪石界面进行分子工程设计，从而提供解决方案，帮助将透闪石太阳能电池推向市场。

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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来源期刊

Nature Reviews Materials Materials Science-Biomaterials

CiteScore

119.40

自引率

0.40%

发文量

107

期刊介绍： Nature Reviews Materials is an online-only journal that is published weekly. It covers a wide range of scientific disciplines within materials science. The journal includes Reviews, Perspectives, and Comments. Nature Reviews Materials focuses on various aspects of materials science, including the making, measuring, modelling, and manufacturing of materials. It examines the entire process of materials science, from laboratory discovery to the development of functional devices.