Alkyl‐Chain‐Regulated Charge Transfer in Fluorescent Inorganic CsPbBr<sub>3</sub> Perovskite Solar Cells

Duan, Jialong; Wang, Yudi; Yang, Xiya; Tang, Qunwei

doi:10.1002/anie.202000199

Cited by 132 publications

(80 citation statements)

References 38 publications

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“…The enhanced PL intensity means the attenuated non-radiative recombination. [27] The sample c shows the highest PL intensity, illustrating the lowest non-radiative recombination. Besides, the obvious red-shift of emission peaks also indicates the reduced non-radiative recombination.…”

Section: Resultsmentioning

confidence: 94%

An Efficient and Stable Perovskite Solar Cell with Suppressed Defects by Employing Dithizone as a Lead Indicator

Hou

Han

et al. 2020

Angew Chem Int Ed

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The defects in perovskite films are one of the most non-negligible factors that can attenuate the performances of perovskite solar cell. This work fabricates defect-reduced perovskite film by using the lead indicator (dithizone) as an additive of perovskite functional layer. The dithizone can retard the crystallization rate of perovskite films, passivate the defects, and enhance the structure stability of perovskite by coordinating with lead atoms. As a result, the device doped with dithizone yields outstanding power conversion efficiency and stability.

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Section: Resultsmentioning

confidence: 94%

An Efficient and Stable Perovskite Solar Cell with Suppressed Defects by Employing Dithizone as a Lead Indicator

Hou

Han

et al. 2020

Angew Chem Int Ed

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“…[71][72][73] However, besides stability, the bandgap of the material and the corresponding efficiency of PSCs are also critical for tandem applications. CsPbBr 3 has a wide bandgap of 2.25 eV [74] , and the state-of-the-art solar cell showed a relatively low power conversion efficiency (PCE) of 10.85%, [75] which is not suitable to couple with Si or CIGS in tandem devices. Further, the mixed halide CsPb(Br x I 1−x ) 3 family, when 0.2 < x <0.4, were reported to show better performance, [72] but their bandgap of ≈1.93 eV is still too large to meet the optimal bandgap values.…”

Section: Inorganic Perovskitesmentioning

confidence: 99%

Perovskite‐Based Tandem Solar Cells: Get the Most Out of the Sun

Zhang

Meng

et al. 2020

Adv Funct Materials

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Tandem solar cells (TSCs) comprising stacked narrow‐bandgap and wide‐bandgap subcells are regarded as the most promising approach to break the Shockley–Queisser limit of single‐junction solar cells. As the game‐changer in the photovoltaic community, organic–inorganic hybrid perovskites became the front‐runner candidate for mating with other efficient photovoltaic technologies in the tandem configuration for higher power conversion efficiency, by virtue of their tunable and complementary bandgaps, excellent photoelectric properties, and solution processability. In this review, a perspective that critically dilates the progress of perovskite material selection and device design for perovskite‐based TSCs, including perovskite/silicon, perovskite/copper indium gallium selenide, perovskite/perovskite, perovskite/CdTe, and perovskite/GaAs are presented. Besides, all‐inorganic perovskite CsPbI3 with high thermal stability is proposed as the top subcell in TSCs due to its suitable bandgap of ≈1.73 eV and rapidly increasing efficiency. To minimize the optical and electrical losses for high‐efficiency TSCs, the optimization of transparent electrodes, recombination layers, and the current‐matching principles are highlighted. Through big data analysis, wide‐bandgap perovskite solar cells with high open‐circuit voltage (Voc) are in dire need in further study. In the end, opportunities and challenges to realize the commercialization of TSCs, including long‐term stability, area upscaling, and mitigation of toxicity, are also envisioned.

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“…Excellent thermal, light, and moisture stabilities have been demonstrated for CsPbBr 3 films and CsPbBr 3 -based devices especially for allinorganic PSC based on CE. [37,[70][71][72]98,99] In the recent two years, PCEs of 10.5-11% have been achieved for CsPbBr 3 -based devices even based on CE. [37,[70][71][72] It is worth noting that a PCE as high as 10.85% was realized for all-inorganic CsPbBr 3 -based devices Reproduced with permission.…”

Section: X-site Substitutionmentioning

confidence: 99%

“…using inorganic materials as HTMs, [71] and a PCE up to 10.91% was demonstrated for CsPbBr 3 -based devices based on organic Spiro-OMeTAD HTM. [72] Although the very impressive stability has been testified for CsPbBr 3 -based devices, its low PCE still hinders its further commercial application, mainly originating from insufficient light harvesting due to the wide bandgap of up to 2.3 eV and serious back contact interfacial recombination losses as well as a large energy barrier.…”

Section: X-site Substitutionmentioning

confidence: 99%

Efficient and Stable All‐Inorganic Perovskite Solar Cells

Chen

Choy

2020

Solar RRL

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The large‐scale commercial application of organic–inorganic hybrid perovskite solar cells (PSCs) based on organic hole transport material (HTM) is still hindered by poor long‐term operational stability, although a certified record power conversion efficiency (PCE) as high as 25.2% can be achieved. In the recent several years, all‐inorganic PSCs have received tremendous attention due to their superb thermal and moisture stability and considerable progresses have been witnessed. Herein, the recent advancements of all‐inorganic PSCs are reviewed comprehensively. First, the recent progresses of the strategies for stabilizing the black phase of inorganic perovskites through either increasing tolerance factor or enhancing the energy barrier of phase transition from black to yellow phase are summarized and discussed. Second, the deposition and growth techniques of inorganic perovskite films are discussed. Third, the effective inorganic HTMs in normal all‐inorganic PSCs are described. Fourth, HTM‐free normal all‐inorganic PSCs are discussed. Afterward, the effective inorganic electron transport materials in inverted all‐inorganic PSCs are discussed. Subsequently, the advancements of interface engineering for increasing the PCE and stability of all‐inorganic PSCs are reviewed. Finally, a brief summary and outlook are presented to push up the PCE of all‐inorganic PSCs to over 20% in the near future.

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Alkyl‐Chain‐Regulated Charge Transfer in Fluorescent Inorganic CsPbBr₃ Perovskite Solar Cells

Cited by 132 publications

References 38 publications

An Efficient and Stable Perovskite Solar Cell with Suppressed Defects by Employing Dithizone as a Lead Indicator

An Efficient and Stable Perovskite Solar Cell with Suppressed Defects by Employing Dithizone as a Lead Indicator

Perovskite‐Based Tandem Solar Cells: Get the Most Out of the Sun

Efficient and Stable All‐Inorganic Perovskite Solar Cells

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Alkyl‐Chain‐Regulated Charge Transfer in Fluorescent Inorganic CsPbBr3 Perovskite Solar Cells

Cited by 132 publications

References 38 publications

An Efficient and Stable Perovskite Solar Cell with Suppressed Defects by Employing Dithizone as a Lead Indicator

An Efficient and Stable Perovskite Solar Cell with Suppressed Defects by Employing Dithizone as a Lead Indicator

Perovskite‐Based Tandem Solar Cells: Get the Most Out of the Sun

Efficient and Stable All‐Inorganic Perovskite Solar Cells

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Product

Resources

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Alkyl‐Chain‐Regulated Charge Transfer in Fluorescent Inorganic CsPbBr₃ Perovskite Solar Cells