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Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit

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Zeitschriftentitel: Advanced Science
Personen und Körperschaften: Wang, Ziyu, Song, Zhaoning, Yan, Yanfa, Liu, Shengzhong (Frank), Yang, Dong
In: Advanced Science, 6, 2019, 7
Format: E-Article
Sprache: Englisch
veröffentlicht:
Wiley
Schlagwörter:
General Physics and Astronomy
General Engineering
Biochemistry, Genetics and Molecular Biology (miscellaneous)
General Materials Science
General Chemical Engineering
Medicine (miscellaneous)
author_facet Wang, Ziyu
Song, Zhaoning
Yan, Yanfa
Liu, Shengzhong (Frank)
Yang, Dong
Wang, Ziyu
Song, Zhaoning
Yan, Yanfa
Liu, Shengzhong (Frank)
Yang, Dong
author Wang, Ziyu
Song, Zhaoning
Yan, Yanfa
Liu, Shengzhong (Frank)
Yang, Dong
spellingShingle Wang, Ziyu
Song, Zhaoning
Yan, Yanfa
Liu, Shengzhong (Frank)
Yang, Dong
Advanced Science
Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
General Physics and Astronomy
General Engineering
Biochemistry, Genetics and Molecular Biology (miscellaneous)
General Materials Science
General Chemical Engineering
Medicine (miscellaneous)
author_sort wang, ziyu
spelling Wang, Ziyu Song, Zhaoning Yan, Yanfa Liu, Shengzhong (Frank) Yang, Dong 2198-3844 2198-3844 Wiley General Physics and Astronomy General Engineering Biochemistry, Genetics and Molecular Biology (miscellaneous) General Materials Science General Chemical Engineering Medicine (miscellaneous) http://dx.doi.org/10.1002/advs.201801704 <jats:title>Abstract</jats:title><jats:p>Up to now, multijunction cell design is the only successful way demonstrated to overcome the Shockley–Quiesser limit for single solar cells. Perovskite materials have been attracting ever‐increasing attention owing to their large absorption coefficient, tunable bandgap, low cost, and easy fabrication process. With their rapidly increased power conversion efficiency, organic–inorganic metal halide perovskite‐based solar cells have demonstrated themselves as the most promising candidates for next‐generation photovoltaic applications. In fact, it is a dream come true for researchers to finally find a perfect top‐cell candidate in tandem device design in commercially developed solar cells like single‐crystalline silicon and CIGS cells used as the bottom component cells. Here, the recent progress of multijunction solar cells is reviewed, including perovskite/silicon, perovskite/CIGS, perovskite/perovskite, and perovskite/polymer multijunction cells. In addition, some perspectives on using these solar cells in emerging markets such as in portable devices, Internet of Things, etc., as well as an outlook for perovskite‐based multijunction solar cells are discussed.</jats:p> Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit Advanced Science
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series Advanced Science
source_id 49
title Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_unstemmed Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_full Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_fullStr Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_full_unstemmed Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_short Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_sort perovskite—a perfect top cell for tandem devices to break the s–q limit
topic General Physics and Astronomy
General Engineering
Biochemistry, Genetics and Molecular Biology (miscellaneous)
General Materials Science
General Chemical Engineering
Medicine (miscellaneous)
url http://dx.doi.org/10.1002/advs.201801704
publishDate 2019
physical
description <jats:title>Abstract</jats:title><jats:p>Up to now, multijunction cell design is the only successful way demonstrated to overcome the Shockley–Quiesser limit for single solar cells. Perovskite materials have been attracting ever‐increasing attention owing to their large absorption coefficient, tunable bandgap, low cost, and easy fabrication process. With their rapidly increased power conversion efficiency, organic–inorganic metal halide perovskite‐based solar cells have demonstrated themselves as the most promising candidates for next‐generation photovoltaic applications. In fact, it is a dream come true for researchers to finally find a perfect top‐cell candidate in tandem device design in commercially developed solar cells like single‐crystalline silicon and CIGS cells used as the bottom component cells. Here, the recent progress of multijunction solar cells is reviewed, including perovskite/silicon, perovskite/CIGS, perovskite/perovskite, and perovskite/polymer multijunction cells. In addition, some perspectives on using these solar cells in emerging markets such as in portable devices, Internet of Things, etc., as well as an outlook for perovskite‐based multijunction solar cells are discussed.</jats:p>
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author Wang, Ziyu, Song, Zhaoning, Yan, Yanfa, Liu, Shengzhong (Frank), Yang, Dong
author_facet Wang, Ziyu, Song, Zhaoning, Yan, Yanfa, Liu, Shengzhong (Frank), Yang, Dong, Wang, Ziyu, Song, Zhaoning, Yan, Yanfa, Liu, Shengzhong (Frank), Yang, Dong
author_sort wang, ziyu
container_issue 7
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container_title Advanced Science
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description <jats:title>Abstract</jats:title><jats:p>Up to now, multijunction cell design is the only successful way demonstrated to overcome the Shockley–Quiesser limit for single solar cells. Perovskite materials have been attracting ever‐increasing attention owing to their large absorption coefficient, tunable bandgap, low cost, and easy fabrication process. With their rapidly increased power conversion efficiency, organic–inorganic metal halide perovskite‐based solar cells have demonstrated themselves as the most promising candidates for next‐generation photovoltaic applications. In fact, it is a dream come true for researchers to finally find a perfect top‐cell candidate in tandem device design in commercially developed solar cells like single‐crystalline silicon and CIGS cells used as the bottom component cells. Here, the recent progress of multijunction solar cells is reviewed, including perovskite/silicon, perovskite/CIGS, perovskite/perovskite, and perovskite/polymer multijunction cells. In addition, some perspectives on using these solar cells in emerging markets such as in portable devices, Internet of Things, etc., as well as an outlook for perovskite‐based multijunction solar cells are discussed.</jats:p>
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imprint Wiley, 2019
imprint_str_mv Wiley, 2019
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publisher Wiley
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series Advanced Science
source_id 49
spelling Wang, Ziyu Song, Zhaoning Yan, Yanfa Liu, Shengzhong (Frank) Yang, Dong 2198-3844 2198-3844 Wiley General Physics and Astronomy General Engineering Biochemistry, Genetics and Molecular Biology (miscellaneous) General Materials Science General Chemical Engineering Medicine (miscellaneous) http://dx.doi.org/10.1002/advs.201801704 <jats:title>Abstract</jats:title><jats:p>Up to now, multijunction cell design is the only successful way demonstrated to overcome the Shockley–Quiesser limit for single solar cells. Perovskite materials have been attracting ever‐increasing attention owing to their large absorption coefficient, tunable bandgap, low cost, and easy fabrication process. With their rapidly increased power conversion efficiency, organic–inorganic metal halide perovskite‐based solar cells have demonstrated themselves as the most promising candidates for next‐generation photovoltaic applications. In fact, it is a dream come true for researchers to finally find a perfect top‐cell candidate in tandem device design in commercially developed solar cells like single‐crystalline silicon and CIGS cells used as the bottom component cells. Here, the recent progress of multijunction solar cells is reviewed, including perovskite/silicon, perovskite/CIGS, perovskite/perovskite, and perovskite/polymer multijunction cells. In addition, some perspectives on using these solar cells in emerging markets such as in portable devices, Internet of Things, etc., as well as an outlook for perovskite‐based multijunction solar cells are discussed.</jats:p> Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit Advanced Science
spellingShingle Wang, Ziyu, Song, Zhaoning, Yan, Yanfa, Liu, Shengzhong (Frank), Yang, Dong, Advanced Science, Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit, General Physics and Astronomy, General Engineering, Biochemistry, Genetics and Molecular Biology (miscellaneous), General Materials Science, General Chemical Engineering, Medicine (miscellaneous)
title Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_full Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_fullStr Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_full_unstemmed Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_short Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
title_sort perovskite—a perfect top cell for tandem devices to break the s–q limit
title_unstemmed Perovskite—a Perfect Top Cell for Tandem Devices to Break the S–Q Limit
topic General Physics and Astronomy, General Engineering, Biochemistry, Genetics and Molecular Biology (miscellaneous), General Materials Science, General Chemical Engineering, Medicine (miscellaneous)
url http://dx.doi.org/10.1002/advs.201801704