A three-dimensional quantum dot network stabilizes perovskite solids via hydrostatic strain

IF 17.3 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Matter Pub Date : 2024-01-03 DOI:10.1016/j.matt.2023.10.015

Yuan Liu , Tong Zhu , Luke Grater , Hao Chen , Roberto dos Reis , Aidan Maxwell , Matthew Cheng , Yitong Dong , Sam Teale , Adam F.G. Leontowich , Chang-Yong Kim , Phoebe Tsz-shan Chan , Mingcong Wang , Watcharaphol Paritmongkol , Yajun Gao , So Min Park , Jian Xu , Jafar Iqbal Khan , Frédéric Laquai , Gilbert C. Walker , Edward H. Sargent

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Abstract

Compressive strain engineering improves perovskite stability. Two-dimensional compressive strain along the in-plane direction can be applied to perovskites through the substrate; however, this in-plane strain results in an offsetting tensile strain perpendicular to the substrate, linked to the positive Poisson ratio of perovskites. Substrate-induced strain engineering has not yet resulted in state-of-the-art operational stability. Here, we seek instead to implement hydrostatic strain in perovskites by embedding lattice-mismatched perovskite quantum dots (QDs) into a perovskite matrix. QD-in-matrix perovskites show a homogeneously strained lattice as evidenced by grazing-incidence X-ray diffraction. We fabricate mixed-halide wide-band-gap (E_g; 1.77 eV) QD-in-matrix perovskite solar cells that maintain >90% of their initial power conversion efficiency (PCE) after 200 h of one-sun operation at the maximum power point (MPP), a significant improvement relative to matrix-only devices, which lose 10% (relative) of their initial PCE after 5 h of MPP tracking.

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三维量子点网络通过静水应变稳定钙钛矿固体

压缩应变工程提高了钙钛矿的稳定性。沿着平面内方向的二维压缩应变可以通过衬底施加到钙钛矿上；然而，这种平面内应变导致垂直于基底的偏移拉伸应变，这与钙钛矿的正泊松比有关。衬底诱导应变工程尚未产生最先进的操作稳定性。在这里，我们试图通过将晶格失配的钙钛矿量子点（QDs）嵌入钙钛矿基质中，在钙钛矿中实现静水应变。基体钙钛矿中的QD显示出均匀应变的晶格，如掠入射X射线衍射所证明的。我们在保持>；在最大功率点（MPP）下一次太阳操作200小时后，其初始功率转换效率（PCE）的90%，相对于仅矩阵的设备而言，这是一个显著的改进，仅矩阵的器件在MPP跟踪5小时后损失了其初始PCE的10%（相对）。

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来源期刊

Matter MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

26.30

自引率

2.60%

发文量

367

期刊介绍： Matter, a monthly journal affiliated with Cell, spans the broad field of materials science from nano to macro levels,covering fundamentals to applications. Embracing groundbreaking technologies,it includes full-length research articles,reviews, perspectives,previews, opinions, personnel stories, and general editorial content. Matter aims to be the primary resource for researchers in academia and industry, inspiring the next generation of materials scientists.