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Modeling Thin Film Solar Cells: From Organic to Perovskite

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Zeitschriftentitel: Advanced Science
Personen und Körperschaften: Li, Deli, Song, Lin, Chen, Yonghua, Huang, Wei
In: Advanced Science, 7, 2020, 1
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 Li, Deli
Song, Lin
Chen, Yonghua
Huang, Wei
Li, Deli
Song, Lin
Chen, Yonghua
Huang, Wei
author Li, Deli
Song, Lin
Chen, Yonghua
Huang, Wei
spellingShingle Li, Deli
Song, Lin
Chen, Yonghua
Huang, Wei
Advanced Science
Modeling Thin Film Solar Cells: From Organic to Perovskite
General Physics and Astronomy
General Engineering
Biochemistry, Genetics and Molecular Biology (miscellaneous)
General Materials Science
General Chemical Engineering
Medicine (miscellaneous)
author_sort li, deli
spelling Li, Deli Song, Lin Chen, Yonghua Huang, Wei 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.201901397 <jats:title>Abstract</jats:title><jats:p>Device model simulation is one of the primary tools for modeling thin film solar cells from organic materials to organic–inorganic perovskite materials. By directly connecting the current density–voltage (<jats:italic>J</jats:italic>–<jats:italic>V</jats:italic>) curves to the underlying device physics, it is helpful in revealing the working mechanism of the heatedly discussed organic–inorganic hybrid perovskite solar cells. Some distinctive optoelectronic features need more phenomenological models and accurate simulations. Herein, the application of the device model method in the simulation of organic and organic–inorganic perovskite solar cells is reviewed. To this end, the ways of the device model are elucidated by discussing the metal–insulator–metal picture and the equations describing the physics. Next, the simulations on <jats:italic>J</jats:italic>–<jats:italic>V</jats:italic> curves of organic solar cells are given in the presence of the space charge, interface, charge injection, traps, or exciton. In the perovskite section, the effects of trap states, direct band recombination, surface recombination, and ion migration on the device performance are systematically discussed from the perspective of the device model simulation. Suggestions for designing perovskite devices with better performance are also given.</jats:p> Modeling Thin Film Solar Cells: From Organic to Perovskite Advanced Science
doi_str_mv 10.1002/advs.201901397
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series Advanced Science
source_id 49
title Modeling Thin Film Solar Cells: From Organic to Perovskite
title_unstemmed Modeling Thin Film Solar Cells: From Organic to Perovskite
title_full Modeling Thin Film Solar Cells: From Organic to Perovskite
title_fullStr Modeling Thin Film Solar Cells: From Organic to Perovskite
title_full_unstemmed Modeling Thin Film Solar Cells: From Organic to Perovskite
title_short Modeling Thin Film Solar Cells: From Organic to Perovskite
title_sort modeling thin film solar cells: from organic to perovskite
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.201901397
publishDate 2020
physical
description <jats:title>Abstract</jats:title><jats:p>Device model simulation is one of the primary tools for modeling thin film solar cells from organic materials to organic–inorganic perovskite materials. By directly connecting the current density–voltage (<jats:italic>J</jats:italic>–<jats:italic>V</jats:italic>) curves to the underlying device physics, it is helpful in revealing the working mechanism of the heatedly discussed organic–inorganic hybrid perovskite solar cells. Some distinctive optoelectronic features need more phenomenological models and accurate simulations. Herein, the application of the device model method in the simulation of organic and organic–inorganic perovskite solar cells is reviewed. To this end, the ways of the device model are elucidated by discussing the metal–insulator–metal picture and the equations describing the physics. Next, the simulations on <jats:italic>J</jats:italic>–<jats:italic>V</jats:italic> curves of organic solar cells are given in the presence of the space charge, interface, charge injection, traps, or exciton. In the perovskite section, the effects of trap states, direct band recombination, surface recombination, and ion migration on the device performance are systematically discussed from the perspective of the device model simulation. Suggestions for designing perovskite devices with better performance are also given.</jats:p>
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author Li, Deli, Song, Lin, Chen, Yonghua, Huang, Wei
author_facet Li, Deli, Song, Lin, Chen, Yonghua, Huang, Wei, Li, Deli, Song, Lin, Chen, Yonghua, Huang, Wei
author_sort li, deli
container_issue 1
container_start_page 0
container_title Advanced Science
container_volume 7
description <jats:title>Abstract</jats:title><jats:p>Device model simulation is one of the primary tools for modeling thin film solar cells from organic materials to organic–inorganic perovskite materials. By directly connecting the current density–voltage (<jats:italic>J</jats:italic>–<jats:italic>V</jats:italic>) curves to the underlying device physics, it is helpful in revealing the working mechanism of the heatedly discussed organic–inorganic hybrid perovskite solar cells. Some distinctive optoelectronic features need more phenomenological models and accurate simulations. Herein, the application of the device model method in the simulation of organic and organic–inorganic perovskite solar cells is reviewed. To this end, the ways of the device model are elucidated by discussing the metal–insulator–metal picture and the equations describing the physics. Next, the simulations on <jats:italic>J</jats:italic>–<jats:italic>V</jats:italic> curves of organic solar cells are given in the presence of the space charge, interface, charge injection, traps, or exciton. In the perovskite section, the effects of trap states, direct band recombination, surface recombination, and ion migration on the device performance are systematically discussed from the perspective of the device model simulation. Suggestions for designing perovskite devices with better performance are also given.</jats:p>
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id ai-49-aHR0cDovL2R4LmRvaS5vcmcvMTAuMTAwMi9hZHZzLjIwMTkwMTM5Nw
imprint Wiley, 2020
imprint_str_mv Wiley, 2020
institution DE-Brt1, DE-Zwi2, DE-D161, DE-Gla1, DE-Zi4, DE-15, DE-Pl11, DE-Rs1, DE-105, DE-14, DE-Ch1, DE-L229, DE-D275, DE-Bn3
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publisher Wiley
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series Advanced Science
source_id 49
spelling Li, Deli Song, Lin Chen, Yonghua Huang, Wei 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.201901397 <jats:title>Abstract</jats:title><jats:p>Device model simulation is one of the primary tools for modeling thin film solar cells from organic materials to organic–inorganic perovskite materials. By directly connecting the current density–voltage (<jats:italic>J</jats:italic>–<jats:italic>V</jats:italic>) curves to the underlying device physics, it is helpful in revealing the working mechanism of the heatedly discussed organic–inorganic hybrid perovskite solar cells. Some distinctive optoelectronic features need more phenomenological models and accurate simulations. Herein, the application of the device model method in the simulation of organic and organic–inorganic perovskite solar cells is reviewed. To this end, the ways of the device model are elucidated by discussing the metal–insulator–metal picture and the equations describing the physics. Next, the simulations on <jats:italic>J</jats:italic>–<jats:italic>V</jats:italic> curves of organic solar cells are given in the presence of the space charge, interface, charge injection, traps, or exciton. In the perovskite section, the effects of trap states, direct band recombination, surface recombination, and ion migration on the device performance are systematically discussed from the perspective of the device model simulation. Suggestions for designing perovskite devices with better performance are also given.</jats:p> Modeling Thin Film Solar Cells: From Organic to Perovskite Advanced Science
spellingShingle Li, Deli, Song, Lin, Chen, Yonghua, Huang, Wei, Advanced Science, Modeling Thin Film Solar Cells: From Organic to Perovskite, General Physics and Astronomy, General Engineering, Biochemistry, Genetics and Molecular Biology (miscellaneous), General Materials Science, General Chemical Engineering, Medicine (miscellaneous)
title Modeling Thin Film Solar Cells: From Organic to Perovskite
title_full Modeling Thin Film Solar Cells: From Organic to Perovskite
title_fullStr Modeling Thin Film Solar Cells: From Organic to Perovskite
title_full_unstemmed Modeling Thin Film Solar Cells: From Organic to Perovskite
title_short Modeling Thin Film Solar Cells: From Organic to Perovskite
title_sort modeling thin film solar cells: from organic to perovskite
title_unstemmed Modeling Thin Film Solar Cells: From Organic to Perovskite
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.201901397