Detail publikačního výsledku
Development of Stable Perovskite Solar Cell
STRACHALA, D.; KRATOCHVÍL, M.; HYLSKÝ, J.; GAJDOŠ, A.; CHLADIL, L.; VANĚK, J.; ČUDEK, P.
Originální název
Development of Stable Perovskite Solar Cell
Anglický název
Development of Stable Perovskite Solar Cell
Druh
Stať ve sborníku v databázi WoS či Scopus
Originální abstrakt
This work deals with the development of stable perovskite solar cell structure. In the research, two sets of perovskite photovoltaic cells were manufactured with a different way of their production. In the first series, an active perovskite layer CH3NH3PbI3-xClx was applied in a glovebox with N2 atmosphere. In the second series was used glove box filled with air with controlled 15% relative humidity. Perovskite solar cells were analyzed for the most frequent degradation mecha-nism, which is moisture. XRD measurements revealed decomposition of the ac-tive perovskite structure with lead iodide increase. XRD measurements, along with EDS analysis, have also confirmed that chlorine is not in the perovskite structure and applies only during the manufacturing process. According to the output parameters of the cells, along with the changes in the perovskite structure, it was found that solar cells manufactured in the controlled humidity environment are more stable. However, they do not achieve such conversion efficiency as cells produced in an inert atmosphere.
Anglický abstrakt
This work deals with the development of stable perovskite solar cell structure. In the research, two sets of perovskite photovoltaic cells were manufactured with a different way of their production. In the first series, an active perovskite layer CH3NH3PbI3-xClx was applied in a glovebox with N2 atmosphere. In the second series was used glove box filled with air with controlled 15% relative humidity. Perovskite solar cells were analyzed for the most frequent degradation mecha-nism, which is moisture. XRD measurements revealed decomposition of the ac-tive perovskite structure with lead iodide increase. XRD measurements, along with EDS analysis, have also confirmed that chlorine is not in the perovskite structure and applies only during the manufacturing process. According to the output parameters of the cells, along with the changes in the perovskite structure, it was found that solar cells manufactured in the controlled humidity environment are more stable. However, they do not achieve such conversion efficiency as cells produced in an inert atmosphere.
Klíčová slova
Perovskite Solar Cells Stability, Effect of Moisture on Perovskite Structure, Perovskite Manufactured at Controlled Humidity
Klíčová slova v angličtině
Perovskite Solar Cells Stability, Effect of Moisture on Perovskite Structure, Perovskite Manufactured at Controlled Humidity
Autoři
STRACHALA, D.; KRATOCHVÍL, M.; HYLSKÝ, J.; GAJDOŠ, A.; CHLADIL, L.; VANĚK, J.; ČUDEK, P.
Rok RIV
2020
Vydáno
17.07.2019
Nakladatel
Springer, Cham
Místo
USA
ISBN
978-3-030-13887-5
Kniha
Renewable Energy Sources: Engineering, Technology, Innovation
Strany od
653
Strany do
665
Strany počet
12
URL
BibTex
@inproceedings{BUT159218,
author="Dávid {Strachala} and Matouš {Kratochvíl} and Josef {Hylský} and Adam {Gajdoš} and Ladislav {Chladil} and Jiří {Vaněk} and Pavel {Čudek}",
title="Development of Stable Perovskite Solar Cell",
booktitle="Renewable Energy Sources: Engineering, Technology, Innovation",
year="2019",
pages="653--665",
publisher="Springer, Cham",
address="USA",
doi="10.1007/978-3-030-13888-2\{_}64",
isbn="978-3-030-13887-5",
url="https://link.springer.com/chapter/10.1007%2F978-3-030-13888-2_64"
}