Tailored Amphiphilic Molecular Mitigators for Stable Perovskite Solar Cells with 23.5% Efficiency

Zhu, Hancheng; Liu, Yuhang; Eickemeyer, Felix T.; Pan, Linfeng; Ren, Dan; Ruiz‐Preciado, Marco A.; Carlsen, Brian; Yang, Bowen; Dong, Xiaofei; Wang, Zaiwei; Liu, Hongli; Wang, Shirong; Zakeeruddin, Shaik M.; Hagfeldt, Anders; Dar, M. Ibrahim; Zhao, Xiaoming; Grätzel, Michaël

doi:10.1002/adma.201907757

Cited by 320 publications

(312 citation statements)

References 38 publications

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“…[ 91 ] Organic ammonium salts have also been reported by Zhu et al to have similar functions. [ 139 ] They judiciously designed a new passivation molecule, 4 ‐ tert ‐butyl‐benzylammonium iodide (tBBAI) in Figure 9c, that significantly enhanced charge extraction from the perovskite film into hole transport layer (HTL), while suppressing carrier radiation‐less recombination. In addition, the hydrophobic tert ‐butyl resists the invasion of moisture, leading to better operational stability.…”

Section: Various Types Of Defectsmentioning

confidence: 99%

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Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Zhou

et al. 2020

Solar RRL

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Figure 3. The impact of MABr treatment on the scanning electron microscopy (SEM) images of film morphology (MAPbI 3 films a) without and b) with MABr treatment), c) ultraviolet-visible (UV-vis) absorption spectra, and d) XRD patterns of the perovskite films. Reproduced with permission. [61] Copyright 2016, Springer Nature. e) Schematic illustration and f) SEM images of the molecule-passivated RP/3D heterostructure. Reproduced with permission. [115] Copyright 2018, Royal Society of Chemistry. g) Schematic representation of the 1D/3D heterostructure evidenced by solid-state NMR proximity measurements. Reproduced with permission. [40] Copyright 2019, Springer Nature. h) Secondary-ion mass spectrometry (SIMS) measurement of interdiffusion-grown MAPbI 3 films on indium tin oxide (ITO) glass. Reproduced with permission.

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Section: Various Types Of Defectsmentioning

confidence: 99%

“…Reproduced with permission. [ 139 ] Copyright 2020, John Wiley and Sons. d) Chemical structures of BAA additives and schematic illustration of defect passivation and water repellence induced by BAA introduced.…”

Section: Various Types Of Defectsmentioning

confidence: 99%

Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Zhou

et al. 2020

Solar RRL

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“…Up to now several approaches have been developed to passivate the defects at the surface of perovskite film, including solvent annealing, additive engineering, post‐treatment, and surface modification . In particular, surface modification fulfilled by depositing a modifier layer atop the perovskite layer is facile with no need to change the fabrication process of the perovskite layer and thus has been extensively utilized . Toward this end, different types of modifiers have been developed; among them, organic salts containing ionic organic functional groups are particularly effective due to their high solubilities in organic solvents and facilities in tuning compositions by changing negative‐ or positive‐charged components .…”

Section: Introductionmentioning

confidence: 99%

Surface Passivation of Perovskite Film by Sodium Toluenesulfonate for Highly Efficient Solar Cells

Zhang

Shang

et al. 2020

Solar RRL

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Ionic defects at the surfaces of organolead halide perovskite films are detrimental to both the efficiency and stability of perovskite solar cells (PSCs). Herein, sodium p-toluenesulfonate (STS) is applied during the surface modification of perovskite layer for the first time, leading to the efficient surface passivation of the perovskite film and consequently significant enhancements in both efficiency and stability of mixed-cation PSC devices. Upon incorporating STS atop the perovskite layer, the power conversion efficiency of the Cs 0.05 MA 0.12 FA 0.83 PbI 2.55 Br 0.45 (abbreviated as CsMAFA) mesoporous-structure mixed-cation PSC devices improves from 18.70% to 20.05% with reduced hysteresis. The sulfonate (-SO 3 À ) anion of STS coordinates with the Pb 2þ of CsMAFA perovskite, and the Na þ cation of STS electrostatically interacts with the anions (I À /Br À ) of CsMAFA perovskite, resulting in the surface passivation of the CsMAFA perovskite film with reduced electron and hole trap state densities. In addition, STS modification induces an upshift of the valence band of perovskite, facilitating hole extraction from the perovskite layer to the hole transport layer with suppressed interfacial charge recombination. Moreover, such a trap state passivation of perovskite film leads to improvement of the ambient stability of PSC devices.

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“…Owing to its advantages (e.g., good transparency, favorable bandgap edge positions in relation to perovskites, environmental stability, and the feasibility of the solution processing with low-fabrication costs), TiO 2 has been widely adopted for the fabrication of high-efficiency PSCs. [9][10][11][12][13][14] An additional layer of thin mesoporous TiO 2 (mp-TiO 2 ) has been generally used to compensate the deficient charge collection efficiency, since of PSCs) by spray coating. Most spray coating for the deposition of inorganic ETLs is done using SnO 2 nanoparticles, but the maximum efficiency is still less than 20%.…”

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confidence: 99%

TiO₂ Colloid‐Spray Coated Electron‐Transporting Layers for Efficient Perovskite Solar Cells

Paik

Lee

Yun

et al. 2020

Advanced Energy Materials

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it provides a larger contact area between the TiO 2 and perovskite. Almost all of the best PSC efficiencies published so far have been obtained by using TiO 2 photoelectrodes. [15-18] Moreover, excellent long-term photo-stability has also been reported in PSCs fabricated using TiO 2 electrodes. [19] mp-TiO 2 layers for PSCs can be formed using spin-coating or screen-printing methods with TiO 2 pastes containing organic binders and surfactants (e.g., ethyl cellulose and terpineol), as well as organic solvents. [20,21] Subsequently, the TiO 2 layers require a follow-up such as high-temperature process to burn out the organic components contained in the TiO 2 paste. The biggest advantage of a hightemperature process would be a lowering of the series resistance of the layer, due to the strong contact between the TiO 2 particles and the TCO substrate. Therefore, in terms of efficiency, high-temperature-processed TiO 2 layers are very desirable; nevertheless, their use may be a large limiting factor in the fabrication of PSCs using a low-temperature continuous coating process or substrates based on an organic material (e.g., polyethylene naphthalate (PEN)). [22] Even PEN-based flexible substrates can be problematic, because they can bend if subjected to a heat treatment at 150 °C. Although recent studies have shown that SnO 2 can be used as an ETLs to fabricate PSCs at relatively low temperature, a heat treatment at temperature ≥150 °C is required to reach the best performances. [23,24] Meanwhile, formamidinium lead triiodide (FAPbI 3)-based perovskites are generally heat-treated at 150 °C to obtain an α-phase. If all the processes for high-efficiency PSCs can be conducted at ≈100 °C, their value will be very high in terms of using flexible substrates and facilitating large-area continuous processes. Currently, most high-efficiency PSCs are fabricated using spin coating, a simple and reliable technique that can produce very uniform thin films. However, since it is problematic to apply spin coating in large-area processes, other methods including blade coating, [25] slot die coating, [26] inkjet printing, [27] and spray coating [28] have been actively studied as scalable deposition techniques. Among these, spray coating has been already widely used in several industry fields and offers great advantages for the continuous production of PSC modules with large areas and a reduced material consumption. [29] So far, several groups reported the deposition of perovskite thin films or of entire ETLs, perovskites, and HTLs (required for the fabrication TiO 2 is one of the most efficient and widely used materials for electrontransporting layer (ETLs) in perovskite solar cells (PSCs). The formation of efficient TiO 2 layers is generally carried out at high temperature by baking at a temperature >400 °C or by vacuum deposition (e.g., atomic layer deposition and E-beam). In this study, the preparation of a TiO 2 ETL for PSCs is reported with excellent properties at low temperatures based on the synthesis of a stable TiO 2 colloidal ...

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Tailored Amphiphilic Molecular Mitigators for Stable Perovskite Solar Cells with 23.5% Efficiency

Cited by 320 publications

References 38 publications

Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Surface Passivation of Perovskite Film by Sodium Toluenesulfonate for Highly Efficient Solar Cells

TiO₂ Colloid‐Spray Coated Electron‐Transporting Layers for Efficient Perovskite Solar Cells

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Tailored Amphiphilic Molecular Mitigators for Stable Perovskite Solar Cells with 23.5% Efficiency

Cited by 320 publications

References 38 publications

Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Surface Passivation of Perovskite Film by Sodium Toluenesulfonate for Highly Efficient Solar Cells

TiO2 Colloid‐Spray Coated Electron‐Transporting Layers for Efficient Perovskite Solar Cells

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TiO₂ Colloid‐Spray Coated Electron‐Transporting Layers for Efficient Perovskite Solar Cells