Planar‐Structure Perovskite Solar Cells with Efficiency beyond 21%

Jiang, Qi; Chu, Zema; Wang, Pengyang; Yang, Xiaolei; Liu, Heng; Wang, Ye; Yin, Zhigang; Wu, Jinliang; Zhang, Qizhou; You, Jingbi

doi:10.1002/adma.201703852

Cited by 1,055 publications

(903 citation statements)

References 41 publications

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“…Additionally, the hysteresis behavior of the devices based on P3HT and PBT1-C has been illustrated in Figure S8 (Supporting Information). [52][53][54] The PCE value and current density of PBT1-C based cells was also checked by the stabilized power output at the maximum power point (MPP) in Figure 4d, yielding a current density of 21.39 mA cm −2 and PCE of 18.82%, which is consistent with the PCE results of the J-V curve. [52][53][54] The PCE value and current density of PBT1-C based cells was also checked by the stabilized power output at the maximum power point (MPP) in Figure 4d, yielding a current density of 21.39 mA cm −2 and PCE of 18.82%, which is consistent with the PCE results of the J-V curve.…”

supporting

confidence: 75%

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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supporting

confidence: 75%

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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“…[36] Solid-State NMR further pointed that there was no proof of the incorporation of Rb or K into the lattice of the mixed-cation FA X MA (1−X) PbI 3 materials. [17,38] SEM images of perovskite on different underlying KCl substrates are shown in Figure 3. Undoubtedly, these results [11,36,37] made the position and the function of K inside organic-inorganic hybrid perovskite materials more controversial.…”

Section: Resultsmentioning

confidence: 99%

Exploring Inorganic Binary Alkaline Halide to Passivate Defects in Low‐Temperature‐Processed Planar‐Structure Hybrid Perovskite Solar Cells

Liu

Zhang

Shi

et al. 2018

Advanced Energy Materials

196

164

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Planar perovskite solar cells obtained by low‐temperature solution processing are of great promise, given a high compatibility with flexible substrates and perovskite‐based tandem devices, whilst benefitting from relatively simple manufacturing methods. However, ionic defects at surfaces usually cause detrimental carrier recombination, which links to one of dominant losses in device performance, slow transient responses, and notorious hysteresis. Here, it is shown that several different types of ionic defects can be simultaneously passivated by simple inorganic binary alkaline halide salts with their cations and anions. Compared to previous literature reports, this work demonstrates a promising passivation technology for perovskite solar cells. The efficient defect passivation significantly suppresses the recombination at the SnO2/perovskite interface, contributing to an increase in the open‐circuit voltage, the fast response of steady‐state efficiency, and the elimination of hysteresis. By this strong leveraging of multiple‐element passivation, low‐temperature‐processed, planar‐structured perovskite solar cells of 20.5% efficiencies, having negligible hysteresis, are obtained. Moreover, this defect‐passivation enhances the stability of solar cells with efficiency beyond 20%, retaining 90% of their initial performance after 30 d. This approach aims at developing the concept of defect engineering, which can be expanded to multiple‐element passivation from monoelement counterparts using simple and low‐cost inorganic materials.

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“…[16] Nowadays, one can meet only few works on highly performing MAPbI 3 perovskites based on non-iodide lead precursor compounds. [23][24][25][26][27][28][29] These latest results were actually the motivation for us to write this review. To form a properly crystalline iodide or iodide/ bromide, perovskite and achieve high performance in solar cells, sources containing only iodide and bromide salts (PbI 2 , PbBr 2 , MAI, FAI, CsI, MABr) are typically used as precursor materials.…”

Section: Introductionmentioning

confidence: 93%

Μethylammonium Chloride: A Key Additive for Highly Efficient, Stable, and Up‐Scalable Perovskite Solar Cells

Kosmatos

Theofylaktos

Giannakaki

et al. 2019

Energy & Environ Materials

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Lead halide perovskites of the type APbX3 (where A = methylammonium MA, formamidinium FA, or cesium and X = iodide and bromide), in a single‐crystal form or more often as polycrystalline films, have already shown unique optoelectronic properties, comparable with those of the best single‐crystal semiconductors. To form a properly crystalline iodide or iodide/bromide, perovskite and achieve high performance in solar cells, sources containing only iodide and bromide salts (PbI2, PbBr2, MAI, FAI, CsI, MABr) are typically used as precursor materials. However, recently, most of the record perovskites contain MACl as additive to control their crystallization, revisiting the importance of methylammonium cation excess and chloride incorporation in perovskites, previously highlighted by Snaith's group back in 2012. Here, we review the background and recent progress in MACl‐mediated crystallization of perovskites, as well as the impact of the additive in solar cells. In particular, we describe the current understanding of the mechanism of perovskite crystallization process and defect passivation at grain boundaries in the presence of MACl. We then discuss the spectacular results (in terms of record efficiencies, stability, and up‐scaling) that have been delivered by solar cells employing MACl‐incorporated perovskites, and give an outlook of future research avenues that might bring perovskite solar cells closer to commercialization.

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Planar‐Structure Perovskite Solar Cells with Efficiency beyond 21%

Cited by 1,055 publications

References 41 publications

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

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

Exploring Inorganic Binary Alkaline Halide to Passivate Defects in Low‐Temperature‐Processed Planar‐Structure Hybrid Perovskite Solar Cells

Μethylammonium Chloride: A Key Additive for Highly Efficient, Stable, and Up‐Scalable Perovskite Solar Cells

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