%0 Journal Article %1 zhang2018low‐temperature %A Zhang, Hua %A Wang, Huan %A Zhu, Hongmei %A Chueh, Chu‐Chen %A Chen, Wei %A Yang, Shihe %A Jen, Alex K.‐Y. %D 2018 %I Wiley Online Library %J Advanced Energy Materials %K HTL new_material perovskite stability %N 13 %R 10.1002/aenm.201702762 %T Low‐Temperature Solution‐Processed CuCrO2 Hole‐Transporting Layer for Efficient and Photostable Perovskite Solar Cells %U https://doi.org/10.1002/aenm.201702762 %V 8 %X Organic–inorganic hybrid perovskite solar cells (PVSCs) have become the front‐running photovoltaic technology nowadays and are expected to profoundly impact society in the near future. However, their practical applications are currently hampered by the challenges of realizing high performance and long‐term stability simultaneously. Herein, the development of inverted PVSCs is reported based on low temperature solution‐processed CuCrO2 nanocrystals as a hole‐transporting layer (HTL), to replace the extensively studied NiOx counterpart due to its suitable electronic structure and charge carrier transporting properties. A ≈45 nm thick compact CuCrO2 layer is incorporated into an inverted planar configuration of indium tin oxides (ITO)/c‐CuCrO2/perovskite/6,6‐phenyl‐C61‐butyric acid methyl ester (PCBM)/bathocuproine (BCP)/Ag, to result in the high steady‐state power conversion efficiency of 19.0% versus 17.1% for the typical low temperature solution‐processed NiOx‐based devices. More importantly, the optimized CuCrO2‐based device exhibits a much enhanced photostability than the reference device due to the greater UV light‐harvesting of the CuCrO2 layer, which can efficiently prevent the perovskite film from intense UV light exposure to avoid associated degradation. The results demonstrate the promising potential of CuCrO2 nanocrystals as an efficient HTL for realizing high‐performance and photostable inverted PVSCs. A new, multifunctional CuCrO2 hole‐transporting layer is developed and incorporated into the inverted perovskite solar cells. The CuCrO2 layer with superior electronic and optical properties is proved to not only enhance the photovoltaic performance but also improve the device photostability via the UV‐blocking effect. Consequently, a high power conversion efficiency of 19.0% with enhanced device photostability is successfully demonstrated.

@article{zhang2018low‐temperature, abstract = {Organic–inorganic hybrid perovskite solar cells (PVSCs) have become the front‐running photovoltaic technology nowadays and are expected to profoundly impact society in the near future. However, their practical applications are currently hampered by the challenges of realizing high performance and long‐term stability simultaneously. Herein, the development of inverted PVSCs is reported based on low temperature solution‐processed CuCrO2 nanocrystals as a hole‐transporting layer (HTL), to replace the extensively studied NiOx counterpart due to its suitable electronic structure and charge carrier transporting properties. A ≈45 nm thick compact CuCrO2 layer is incorporated into an inverted planar configuration of indium tin oxides (ITO)/c‐CuCrO2/perovskite/[6,6]‐phenyl‐C61‐butyric acid methyl ester (PCBM)/bathocuproine (BCP)/Ag, to result in the high steady‐state power conversion efficiency of 19.0% versus 17.1% for the typical low temperature solution‐processed NiOx‐based devices. More importantly, the optimized CuCrO2‐based device exhibits a much enhanced photostability than the reference device due to the greater UV light‐harvesting of the CuCrO2 layer, which can efficiently prevent the perovskite film from intense UV light exposure to avoid associated degradation. The results demonstrate the promising potential of CuCrO2 nanocrystals as an efficient HTL for realizing high‐performance and photostable inverted PVSCs. A new, multifunctional CuCrO2 hole‐transporting layer is developed and incorporated into the inverted perovskite solar cells. The CuCrO2 layer with superior electronic and optical properties is proved to not only enhance the photovoltaic performance but also improve the device photostability via the UV‐blocking effect. Consequently, a high power conversion efficiency of 19.0% with enhanced device photostability is successfully demonstrated.}, added-at = {2018-07-03T11:30:33.000+0200}, author = {Zhang, Hua and Wang, Huan and Zhu, Hongmei and Chueh, Chu‐Chen and Chen, Wei and Yang, Shihe and Jen, Alex K.‐Y.}, biburl = {https://www.bibsonomy.org/bibtex/2fcc1d207cda4edee53b23f5944c16197/bretschneider_m}, doi = {10.1002/aenm.201702762}, interhash = {d5bec5420a8e8ac09c29f9766d0c179d}, intrahash = {fcc1d207cda4edee53b23f5944c16197}, issn = {1614-6832}, journal = {Advanced Energy Materials}, keywords = {HTL new_material perovskite stability}, month = {5}, number = 13, publisher = {Wiley Online Library}, timestamp = {2018-07-03T11:30:33.000+0200}, title = {Low‐Temperature Solution‐Processed CuCrO2 Hole‐Transporting Layer for Efficient and Photostable Perovskite Solar Cells}, url = {https://doi.org/10.1002/aenm.201702762}, volume = 8, year = 2018 }