2D Intermediate Suppression for Efficient Ruddlesden–Popper (RP) Phase Lead-Free Perovskite Solar Cells

Qiu, Jian; Xia, Yingdong; Zheng, Yiting; Hui, Wei; Gu, Hao; Yuan, Wenbo; Yu, Hui; Chao, Lingfeng; Niu, Tingting; Yang, Yingguo; Gao, Xingyu; Chen, Yonghua; Huang, Wei

doi:10.1021/acsenergylett.9b00954

Cited by 185 publications

(182 citation statements)

References 54 publications

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“…Later, Qiu et al explored the synergy between BA and PEA to control the crystallization process. [ 120 ] The interaction of BA and PEA could effectively inhibit the formation of mesophase during crystal growth, as shown in Figure 7b. As a result, a high‐quality thin film was obtained and the crystal orientation was improved.…”

Section: Strategies For Improving Stabilitymentioning

confidence: 99%

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Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX₃) Solar Cells

et al. 2020

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Although lead‐based perovskite solar cells (PSCs) are highly efficient, the toxicity of lead (Pb) limits its large‐scale commercialization. As such, there is an urgent need to find alternatives. Many studies have examined tin‐based PSCs. However, pure tin‐based perovskites are easily oxidized in the air or just in glovebox with an ultrasmall amount of oxygen. Such a characteristic makes their performance and stability less ideal compared with those of lead‐based perovskites. Herein, how to address the instability of tin‐based perovskites is introduced in detail. First, the crystalline structure, optical properties, and sources of instability of tin‐based perovskites are summarized. Next, the preparation methods of tin‐based perovskite are discussed. Then, various measures for solving the instability problem are explained using four strategies: additive engineering, deoxidizer, partial substitution, and reduced dimensions. Finally, the challenges and prospects are laid out to help researchers develop highly efficient and stable tin‐based perovskites in the future.

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Section: Strategies For Improving Stabilitymentioning

confidence: 99%

“…Reproduce with permission. [ 120 ] Copyright 2019, American Chemical Society Publications. c) The perovskite structures of single crystals with HEAI proportions 0%, 40%, 80%, and 100% represented from left to right.…”

Section: Strategies For Improving Stabilitymentioning

confidence: 99%

Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX₃) Solar Cells

et al. 2020

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“…Furthermore, the intermediate phase that blocked the uniform and orderly nucleation of the perovskite crystal was also effectively suppressed by using 2DRP (BA 0.5 PEA 0.5 ) 2 FA 3 Sn 4 I 13 , resulting in a high PCE (ca. 8.82 %) and improved stability . Thus, great progress has been made in the systematic study of 2DRP Sn‐based perovskites.…”

Section: Introductionmentioning

confidence: 99%

“…8.82 %) and improved stability. [28] Thus, great progress has been made in the systematic study of 2DRP Sn-based perovskites.A part from RP perovskite,2 Dp erovskites also contain am ore stable Dion-Jacobson (DJ) structure owing to the alternating hydrogen bonding interactions between diammonium cations and inorganic slabs. [29] Unlike RP phases (1/2, 1/2 displacements), the DJ phases feature short divalent + 2c ations between the layers,w hich yield an eclipsed stacking arrangement (0, 0d isplacements) that weakens the quantum confinement.…”

Section: Introductionmentioning

confidence: 99%

Low‐Dimensional Dion–Jacobson‐Phase Lead‐Free Perovskites for High‐Performance Photovoltaics with Improved Stability

et al. 2020

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1,4‐butanediamine (BEA) is incorporated into FASnI3 (FA=formamidinium) to develop a series of lead‐free low‐dimensional Dion–Jacobson‐phase perovskites, (BEA)FAn−1SnnI3n+1. The broadness of the (BEA)FA2Sn3I10 band gap appears to be influenced by the structural distortion owing to high symmetry. The introduction of BEA ligand stabilizes the low‐dimensional perovskite structure (formation energy ca. 106 j mol−1), which inhibits the oxidation of Sn2+. The compact (BEA)FA2Sn3I10 dominated film enables a weakened carrier localization mechanism with a charge transfer time of only 0.36 ps among the quantum wells, resulting in a carrier diffusion length over 450 nm for electrons and 340 nm for holes, respectively. Solar cell fabrication with (BEA)FA2Sn3I10 delivers a power conversion efficiency (PCE) of 6.43 % with negligible hysteresis. The devices can retain over 90 % of their initial PCE after 1000 h without encapsulation under N2 environment.

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“…The addition of BAI had improved the PCE from 4.0% (3D) to 5.5%. The addition of EDI 2 doped device further improved the initial PCE to 7.4%, and the PCE continuously increased to 8.9% stored in a glovebox for over 1400 h [118]. Based on inverted FASnI3 PSCs, Chen et al introduced an ultrathin phenylethylammonium bromide (PEABr) between perovskite and HTL layer (Figure 15), leading to reduced trap states and suppressed charge recombination in 2D/3D PSCs.…”

Section: D/3d Sn Perovskite Solar Cellsmentioning

confidence: 99%

The Low-Dimensional Three-Dimensional Tin Halide Perovskite: Film Characterization and Device Performance

Gai

Wang

et al. 2019

Energies

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Halide perovskite solar cells (PSCs) are considered as one of the most promising candidates for the next generation solar cells as their power conversion efficiency (PCE) has rapidly increased up to 25.2%. However, the most efficient halide perovskite materials all contain toxic lead. Replacing the lead cation with environmentally friendly tin (Sn) is proposed as an important alternative. Today, the inferior performance of Sn-based PSCs mainly due to two challenging issues, namely the facile oxidation of Sn2+ to Sn4+ and the low formation energies of Sn vacancies. Two-dimensional (2D) halide perovskite, in which the large sized organic cations confine the corner sharing BX6 octahedra, exhibits higher formation energy than that of three-dimensional (3D) structure halide perovskite. The approach of mixing a small amount of 2D into 3D Sn-based perovskites was demonstrated as an efficient method to produce high performance perovskite films. In this review, we first provide an overview of key points for making high performance PSCs. Then we give an introduction to the physical parameters of 3D ASnX3 (MA+, FA+, and Cs+) perovskite and a photovoltaic device based on them, followed by an overview of 2D/3D halide perovskites based on ASnX3 (MA+ and FA+) and their optoelectronic applications. The current challenges and a future outlook of Sn-based PSCs are discussed in the end. This review will give readers a better understanding of the 2D/3D Sn-based PSCs.

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2D Intermediate Suppression for Efficient Ruddlesden–Popper (RP) Phase Lead-Free Perovskite Solar Cells

Cited by 185 publications

References 54 publications

Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX₃) Solar Cells

Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX₃) Solar Cells

Low‐Dimensional Dion–Jacobson‐Phase Lead‐Free Perovskites for High‐Performance Photovoltaics with Improved Stability

The Low-Dimensional Three-Dimensional Tin Halide Perovskite: Film Characterization and Device Performance

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2D Intermediate Suppression for Efficient Ruddlesden–Popper (RP) Phase Lead-Free Perovskite Solar Cells

Cited by 185 publications

References 54 publications

Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX3) Solar Cells

Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX3) Solar Cells

Low‐Dimensional Dion–Jacobson‐Phase Lead‐Free Perovskites for High‐Performance Photovoltaics with Improved Stability

The Low-Dimensional Three-Dimensional Tin Halide Perovskite: Film Characterization and Device Performance

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Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX₃) Solar Cells

Strategies for Improving the Stability of Tin‐Based Perovskite (ASnX₃) Solar Cells