Charge-Transporting-Layer-Free, Vacuum-Free, All-Inorganic CsPbIBr2 Perovskite Solar Cells Via Dipoles-Adjusted Interface

Zhang, Wentao; Zhang, Zeyulin; Jiang, Qubo; Wei, Ziming; Zhang, Yuting; You, Hailong; Chen, Dazheng; He, Fengqin; Zhang, Zeyang

doi:10.3390/nano10071324

Cited by 11 publications

(13 citation statements)

References 35 publications

(51 reference statements)

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“…The champion cell, where TiO 2 was used as an ETL, gave a PCE of 13.7%, which is higher than the record experimental value of 11.53% [42]. To date, much focus has been made on HTL-free CsPbIBr2-based devices [15,21,31,34], and our findings suggest that many of the experimentally tested devices could be significantly enhanced by the addition of an appropriate HTL.…”

Section: Cspbibr 2 -Based Solar Cellsmentioning

confidence: 51%

“…Based on these papers, IPA appears to be an antisolvent that lends itself well to approaches where only DMSO is used as a solvent, however, as soon as DMF is added to the solvent, other antisolvents perform better. Since initial literature reviews of researchers working on CsPbIBr 2 may not include sister materials, and the vast majority of CsPbIBr 2 films are made with DMSO [31,34,35,42], our findings should be taken into account by other researchers, since they may not be aware that there is an alternative antisolvent quenching method available to the one presented by Zhang et al…”

Section: Discussionmentioning

confidence: 96%

“…[21,33]. Moreover, CsPbIBr 2 films have been deposited via: one-step spin coating [30,31,34], a gas-assisted method [35], a spray-assisted method [25], a two-step spin coating method [21] and by dual-source thermal evaporation [15]. While antisolvent quenching has been shown to significantly improve a range of perovskite materials [36][37][38][39], we were surprised to note a lack of literature reporting its use with CsPbIBr 2 , with Liu et al reporting its use in a vapour-assisted deposition [40] and only Zhang et al reporting the use of antisolvents with a one-step spin coating procedure.…”

Section: Introductionmentioning

confidence: 99%

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Enhancing the stability and crystallinity of CsPbIBr2 through antisolvent engineering

2021

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All inorganic lead-based perovskites containing bromine-iodine alloys, such as CsPbIBr2, have arisen as one of the most attractive candidates for absorber layers in solar cells. That said, there remains a large gap when it comes to film and crystal quality between the inorganic and hybrid perovskites. In this work, antisolvent engineering is employed as a simple and reproducible method for improving CsPbIBr2 thin films. We found that both the antisolvent used and the conditions under which it was applied have a measurable impact on both the quality and stability of the final product. We arrived at this conclusion by characterising the samples using scanning electron microscopy, X-ray diffraction, UV–visible and photoluminescence measurements, as well as employing a novel system to quantify stability. Our findings, and the application of our novel method for quantifying stability, demonstrate the ability to significantly enhance CsPbIBr2 samples, produced via a static one-step spin coating method, by applying isopropanol 10 s after commencing the spin programme. The antisolvent quenched CsPbIBr2 films demonstrate both improved crystallinity and an extended lifespan.

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Section: Cspbibr 2 -Based Solar Cellsmentioning

confidence: 51%

Section: Discussionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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Enhancing the stability and crystallinity of CsPbIBr2 through antisolvent engineering

2021

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“…and hole selective layers (HSLs) are used in high-efficiency PSCs, but they make the device as unstable one like organic HSLs (spiro-OMeTAD, PEDOT: PSS, etc.). 21,22 Hence, researchers are drawn to HSL-free carbon-electrodebased PSCs (C-PSCs), which are advantageous due to carbon's low cost, simple deposition process, chemical stability, hydrophobicity and high hole extraction capability. 22 Carbon layer in C-PSCs mainly protects the perovskite layer from moisture and increases the stability of device under ambient conditions.…”

Section: Introductionmentioning

confidence: 99%

Low‐temperature crystallization and growth of CsPbIBr ₂ films through PbX ₂ ‐DMSO adduct towards stable and efficient carbon‐based all‐inorganic perovskite solar cells

Choubey¹,

Nagapandiselvi²,

Santhosh³

et al. 2022

Intl J of Energy Research

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Summary In the realm of solar cells, currently, the carbon‐electrode‐based, all‐inorganic perovskite solar cells (C‐IPSCs) based on cesium lead mixed halide perovskites have drawn much attention. Band‐gap tunability and environmental stability of these perovskites (CsPbIBr2) have been gaining attraction as a suitable absorber material for device fabrication. Fabrication of a high‐performing and stable C‐IPSC based on CsPbIBr2 is a challenging process due to high‐temperature fabrication, poor solution deposition of perovskite film, and high recombination at perovskite/carbon interface. In this work, a simple single‐step deposition process was adopted to engineer a good quality perovskite film by replacing conventional precursors with DMSO‐adducts of lead halide (PbX2). Incorporation of the adduct‐based precursor enables crystallization of CsPbIBr2 at a low temperature (~150°C). This enhances the crystallinity of the film, improves the grain size and defects passivation which imparts endurance to the perovskite against phase change and thermal stress. Thereby, enhancing the light absorption and suppressing the non‐radiative recombination in CsPbIBr2 film. As a result, the open‐circuit voltage is enhanced up to 1.18 V and fill factor up to 57%, further improving the power conversion efficiency by 59.4% leading to a champion device efficiency of 5.9%. Adduct‐based C‐IPSC displayed substantial enhancement of ambient stability and the adduct‐based perovskite exhibited excellent thermal stability.

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“…The performance of the device based on the all-inorganic perovskite and titanium dioxide presented power conversion efficiency up to 6.39%. Finally, in the Special Issue, a simplified vertical structure of FTO–CsPbIBr 2 –carbon upon interfacial modification with polyethyleneimine species is suggested, yielding a power conversion efficiency of 4.9% with an open circuit voltage of 0.9 V and a fill factor of 50.4% [ 9 ].…”

mentioning

confidence: 99%

Special Issue: Perovskite Nanostructures: From Material Design to Applications

Κωστοπούλου

Vernardou

2021

Nanomaterials

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In the past decade, perovskite materials have attracted great scientific and technological interest due to their interesting opto-electronic properties. Nanostructuring of the perovskites, due to their reduced dimensions are advantageous in offering large surface area, controlled transport and charge carrier mobility, strong absorption and photoluminescence, and confinement effects. These features, together with the unique tunability in composition, shape, and functionalities in addition to the ability to form efficient, low-cost, and light-active structures make the perovskite nanostructures efficient functional components for multiple applications, ranging from photovoltaics and batteries to lasing and light-emitting diodes. The purpose of this Special Issue is to give an overview of the latest experimental findings concerning the tunability in composition, shape, functionalities, growth conditions, and synthesis procedures of perovskite structures and to identify the critical parameters for producing materials with functional characteristics.

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Charge-Transporting-Layer-Free, Vacuum-Free, All-Inorganic CsPbIBr2 Perovskite Solar Cells Via Dipoles-Adjusted Interface

Cited by 11 publications

References 35 publications

Enhancing the stability and crystallinity of CsPbIBr2 through antisolvent engineering

Enhancing the stability and crystallinity of CsPbIBr2 through antisolvent engineering

Low‐temperature crystallization and growth of CsPbIBr ₂ films through PbX ₂ ‐DMSO adduct towards stable and efficient carbon‐based all‐inorganic perovskite solar cells

Special Issue: Perovskite Nanostructures: From Material Design to Applications

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Charge-Transporting-Layer-Free, Vacuum-Free, All-Inorganic CsPbIBr2 Perovskite Solar Cells Via Dipoles-Adjusted Interface

Cited by 11 publications

References 35 publications

Enhancing the stability and crystallinity of CsPbIBr2 through antisolvent engineering

Enhancing the stability and crystallinity of CsPbIBr2 through antisolvent engineering

Low‐temperature crystallization and growth of CsPbIBr 2 films through PbX 2 ‐DMSO adduct towards stable and efficient carbon‐based all‐inorganic perovskite solar cells

Special Issue: Perovskite Nanostructures: From Material Design to Applications

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Low‐temperature crystallization and growth of CsPbIBr ₂ films through PbX ₂ ‐DMSO adduct towards stable and efficient carbon‐based all‐inorganic perovskite solar cells