Surface passivation engineering strategy to fully-inorganic cubic CsPbI3 perovskites for high-performance solar cells

Li, Bo; Zhang, Yanan; Fu, Lin; Tong, Ying; Zhou, Shujie; Zhang, Luyuan; Yin, Longwei

doi:10.1038/s41467-018-03169-0

Cited by 537 publications

(502 citation statements)

References 35 publications

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“…These values correlate well with the relative J SC for each antisolvent, demonstrating that the band edge absorption is mainly limiting the J SC . Although CsPbI 3 device operational stability is outside of the scope of this work, there are many methods used to improve stability which could synergistically be combined with this work to further improve stability …”

Section: Resultsmentioning

confidence: 99%

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

Moot

Marshall

Wheeler

et al. 2020

Advanced Energy Materials

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The excellent optoelectronic properties demonstrated by hybrid organic/inorganic metal halide perovskites are all predicated on precisely controlling the exact nucleation and crystallization dynamics that occur during film formation. In general, high‐performance thin films are obtained by a method commonly called solvent engineering (or antisolvent quench) processing. The solvent engineering method removes excess solvent, but importantly leaves behind solvent that forms chemical adducts with the lead‐halide precursor salts. These adduct‐based precursor phases control nucleation and the growth of the polycrystalline domains. There has not yet been a comprehensive study comparing the various antisolvents used in different perovskite compositions containing cesium. In addition, there have been no reports of solvent engineering for high efficiency in all‐inorganic perovskites such as CsPbI3. In this work, inorganic perovskite composition CsPbI3 is specifically targeted and unique adducts formed between CsI and precursor solvents and antisolvents are found that have not been observed for other A‐site cation salts. These CsI adducts control nucleation more so than the PbI2–dimethyl sulfoxide (DMSO) adduct and demonstrate how the A‐site plays a significant role in crystallization. The use of methyl acetate (MeOAc) in this solvent engineering approach dictates crystallization through the formation of a CsI–MeOAc adduct and results in solar cells with a power conversion efficiency of 14.4%.

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Section: Resultsmentioning

confidence: 99%

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

Moot

Marshall

Wheeler

et al. 2020

Advanced Energy Materials

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“…Huang et al used sulfobetaine zwitterions to develop PSCs that exhibited a PCE of 11.4% without efficiency degradation after being exposed to air with ≈85% humidity for over 30 days . Using a polymer additive (polyvinylpyrrolidone), Yin et al prepared CsPbI 3 a PSC with good moisture stability . More recently, inorganic quasi‐2D CsPbX 3 (X = halide) emerged, was systematically studied, and delivered a PCE of 12.4% for a CsPbI 3 PSC with greatly improved stability .…”

Section: Comparison Of Parameters For Pscs Based On Cspbi2br Films Momentioning

confidence: 99%

Synergy of Hydrophobic Surface Capping and Lattice Contraction for Stable and High‐Efficiency Inorganic CsPbI₂Br Perovskite Solar Cells

et al. 2018

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CsPbI2Br has been recognized as a promising material for photovoltaic applications due to its excellent optoelectronic properties and compositional stability. Unfortunately, its desired perovskite phase is not stable in humid environments as it is spontaneously transformed into a yellow non‐perovskite phase. Herein, we present our strategy to use phenylethylammonium chlorine (PEACl) treatment to significantly improve the moisture‐resistance of the CsPbI2Br film without compromising its high solar cell efficiency. It is found that: 1) small‐sized hydrophobic aromatic group PEA+ forms in the edge‐on orientation on the CsPbI2Br surface and 2) smaller halide Cl− is doped into the CsPbI2Br lattice during post‐annealing, leading to a smaller lattice structure with beneficial crystallization quality. Compared with the reference sample without the PEACl treatment, the present device achieves a comparable power‐conversion efficiency of 14.05% and much improved moisture resistance.

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“…However, the negative charges in PBT1-C were mainly concentrated on the carbonyl (CO) groups, which can act as a Lewis base to passivate the under-coordinated Pb atoms. [32,[45][46][47] In order to investigate the charge transfer dynamics from the perovskite to HTMs, steady-state photoluminescence (PL) and time-resolved photoluminescence (TRPL) were measured by depositing different HTM onto perovskite films. In Figure 2b, the pure PBT1-C exhibited a peak of CO bond at 1660 cm −1 in the FTIR spectrum, however, the blend sample of PBT1-C:PbI 2 showed a blue-shifted peak of 1648 cm −1 .…”

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confidence: 99%

A Dopant‐Free Polymeric Hole‐Transporting Material Enabled High Fill Factor Over 81% for Highly Efficient Perovskite Solar Cells

Feng

Deng

et al. 2019

Advanced Energy Materials

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Although perovskite solar cells (PVSCs) have achieved rapid progress in the past few years, most of the high‐performance device results are based on the doped small molecule hole‐transporting material (HTM), spiro‐OMeTAD, which affects their long‐term stability. In addition, some defects from under‐coordinated Pb atoms on the surface of perovskite films can also result in nonradiative recombination to affect device performance. To alleviate these problems, a dopant‐free HTM based on a donor‐acceptor polymer, PBT1‐C, synthesized from the copolymerization between the benzodithiophene and 1,3‐bis(4‐(2‐ethylhexyl)thiophen‐2‐yl)‐5,7‐bis(2‐alkyl)benzo[1,2‐c:4,5‐c′]dithiophene‐4,8‐dione units is introduced. PBT1‐C not only possesses excellent hole mobility, but is also able to passivate the surface traps of the perovskite films. The derived PVSC shows a high power conversion efficiency of 19.06% with a very high fill factor of 81.22%, which is the highest reported for dopant‐free polymeric HTMs. The results from photoluminescence and trap density of states measurements validate that PBT1‐C can effectively passivate both surface and grain boundary traps of the perovskite.

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Surface passivation engineering strategy to fully-inorganic cubic CsPbI3 perovskites for high-performance solar cells

Cited by 537 publications

References 35 publications

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

Synergy of Hydrophobic Surface Capping and Lattice Contraction for Stable and High‐Efficiency Inorganic CsPbI₂Br Perovskite Solar Cells

A Dopant‐Free Polymeric Hole‐Transporting Material Enabled High Fill Factor Over 81% for Highly Efficient Perovskite Solar Cells

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Surface passivation engineering strategy to fully-inorganic cubic CsPbI3 perovskites for high-performance solar cells

Cited by 537 publications

References 35 publications

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

CsI‐Antisolvent Adduct Formation in All‐Inorganic Metal Halide Perovskites

Synergy of Hydrophobic Surface Capping and Lattice Contraction for Stable and High‐Efficiency Inorganic CsPbI2Br Perovskite Solar Cells

A Dopant‐Free Polymeric Hole‐Transporting Material Enabled High Fill Factor Over 81% for Highly Efficient Perovskite Solar Cells

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Synergy of Hydrophobic Surface Capping and Lattice Contraction for Stable and High‐Efficiency Inorganic CsPbI₂Br Perovskite Solar Cells