Interfacial Engineering for High-Efficiency Nanorod Array-Structured Perovskite Solar Cells

In the last decade, photovoltaic devices employing lead halide perovskites as light absorber have pulled the attention of researchers due to their outstanding performance. However, the lead halide perovskite based photovoltaic devices suffering from the toxicity of lead (Pb) and lower stability in air. Herein, we have replaced Pb with less toxic antimony (Sb) to prepare air stable and Pb‐free perovskite light absorber. Moreover, we have developed a two‐step procedure to prepare the high quality films of perovskite light absorber with device architecture of FTO/CL‐TiO2/m‐TiO2/MASbI/HTM/Au. This fabricated Pb‐free perovskite solar cell device prepared with two‐step procedure shows good performance with remarkably good open circuit voltage of 740 mV.

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“…Cao et al . have employed TiO 2 nanorods array and achieved an excellent PCE of 20.2 % . In another report, Yang et al .…”

Section: Methodsmentioning

confidence: 99%

A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH₃NH₃)₃Sb₂I₉ Perovskite with Improved Open Circuit Voltage and Performance

2020

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“…To the best of our knowledge, this is the highest cell performance reported for TiO 2 rutile NR‐based devices fabricated with methylammonium lead triiodide (MAPbI 3 ) light absorber (see Table S2 in the Supporting Information for a summary of the highest cell performance values reported in the literature). Perspective wise, we expect further enhancements in cell efficiency by replacing MAPI with more recently developed and better performing light absorbers, such as mixed cation/anion hybrid perovskite materials …”

Section: Resultsmentioning

confidence: 99%

Engineering of the Electron Transport Layer/Perovskite Interface in Solar Cells Designed on TiO₂ Rutile Nanorods

Shahvaranfard

Altomare

Hou

et al. 2020

Adv Funct Materials

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The engineering of the electron transport layer (ETL)/light absorber interface is explored in perovskite solar cells. Single‐crystalline TiO2 nanorod (NR) arrays are used as ETL and methylammonium lead iodide (MAPI) as light absorber. A dual ETL surface modification is investigated, namely by a TiCl4 treatment combined with a subsequent PC61BM monolayer deposition, and the effects on the device photovoltaic performance were evaluated with respect to single modifications. Under optimized conditions, for the combined treatment synergistic effects are observed that lead to remarkable enhancements in cell efficiency, from 14.2% to 19.5%, and to suppression of hysteresis. The devices show JSC, VOC, and fill factor as high as 23.2 mA cm−2, 1.1 V, and 77%, respectively. These results are ascribed to a more efficient charge transfer across the ETL/perovskite interface, which originates from the passivation of defects and trap states at the ETL surface. To the best of our knowledge, this is the highest cell performance ever reported for TiO2 NR‐based solar cells fabricated with conventional MAPI light absorber. Perspective wise, this ETL surface functionalization approach combined with more recently developed and better performing light absorbers, such as mixed cation/anion hybrid perovskite materials, is expected to provide further performance enhancements.

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“…[61][62][63][64][65][66] In the past few decades, ILs have gradually emerged in terms of catalysis, [67] extraction, [68][69][70] non-volatile solvents, [71,72] gas absorption, [73][74][75] etc. With the recent development of electronic technology, [76] ILs are increasingly being used in energy storage, [77] sensing and flexible display, [78] etc. Meanwhile, an increasing number of novel ILs have been developed.…”

Section: The Properties Of Ionic Liquidmentioning

confidence: 99%

Overview of Ionogels in Flexible Electronics

Zhang

Jiang

Dong

et al. 2020

The Chemical Record

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Ionogels have aroused wide interests in the field of flexible electronics. The combination of solid‐state networks and ionic liquids opens up thousands of possibilities for ionogels. The unique structures of ionogels endow them excellent mechanical properties, conductivity and thermal stability to approach the challenge of flexible electronic. A large number of new ionogels have been developed by different methods including the exchange of solution, polymeric ionic liquid and in‐situ reactions in ionic liquids (gelation of low molecular weight gelators, self‐assembly of block polymers, formation of double‐network structure, ionogel nanocomposites and direct polymerization of polymerizable monomers). The aim of this review is to discuss different preparation methods of ionogels and the comparison of their advantages.

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Interfacial Engineering for High-Efficiency Nanorod Array-Structured Perovskite Solar Cells

Cited by 48 publications

References 68 publications

A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH₃NH₃)₃Sb₂I₉ Perovskite with Improved Open Circuit Voltage and Performance

A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH₃NH₃)₃Sb₂I₉ Perovskite with Improved Open Circuit Voltage and Performance

Engineering of the Electron Transport Layer/Perovskite Interface in Solar Cells Designed on TiO₂ Rutile Nanorods

Overview of Ionogels in Flexible Electronics

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Interfacial Engineering for High-Efficiency Nanorod Array-Structured Perovskite Solar Cells

Cited by 48 publications

References 68 publications

A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH3NH3)3Sb2I9 Perovskite with Improved Open Circuit Voltage and Performance

A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH3NH3)3Sb2I9 Perovskite with Improved Open Circuit Voltage and Performance

Engineering of the Electron Transport Layer/Perovskite Interface in Solar Cells Designed on TiO2 Rutile Nanorods

Overview of Ionogels in Flexible Electronics

Contact Info

Product

Resources

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A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH₃NH₃)₃Sb₂I₉ Perovskite with Improved Open Circuit Voltage and Performance

A Two‐Step Modified Sequential Deposition Method‐based Pb‐Free (CH₃NH₃)₃Sb₂I₉ Perovskite with Improved Open Circuit Voltage and Performance

Engineering of the Electron Transport Layer/Perovskite Interface in Solar Cells Designed on TiO₂ Rutile Nanorods