Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell
The study encompasses the idea to employ a single bandgap-graded transport layer in lieu of two different (transparent conducting oxide and electron transport layer) layers in the perovskite solar cell to increase the overall device functionality. Numerical simulation has been used to investigate th...
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my.uniten.dspace-340702024-10-14T11:17:51Z Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell Ahmed S. Akhtaruzzaman M. Zulhafizhazuan W. Yusoff Y. Alnaser I.A. Karim M.R. Shahiduzzaman M. Sobayel K. 58573844800 57195441001 57196150697 57206844407 56741226700 56820318000 55640096500 57194049079 defect density GZO interface defect perovskite SCAPS-1D Activation energy Conversion efficiency Defect density Electric resistance Electron transport properties Energy gap Gallium compounds II-VI semiconductors Numerical models Perovskite solar cells Transparent conducting oxides Zinc oxide Bandgap graded Charge transport layer Defects density Ga-doped ZnO GZO Inorganics Interface defects Power conversion efficiencies SCAPS-1D Transport layers Perovskite The study encompasses the idea to employ a single bandgap-graded transport layer in lieu of two different (transparent conducting oxide and electron transport layer) layers in the perovskite solar cell to increase the overall device functionality. Numerical simulation has been used to investigate the cell performance parameters. The thickness of the absorber layer has been altered in relation to the defect density to identify the optimal cell parameter values. Maximum power conversion efficiency (PCE) has been recorded as 22.17% at 1E13 cm?3 defect density in the absorber. These findings demonstrate the numerical modeling limitations for the relationship between defect mechanism and performance. The activation energy and effects of series resistance (R s) on solar cells have also been assessed. The temperature degradation gradient of the proposed structure GZO/CsGeI3/NiO/Au has been found to be 3% only with a PCE of 22.17%, which validates the concept of using a bandgap-graded transport layer and paves the way for a new era for perovskite research. � 2023 The Japan Society of Applied Physics. Final 2024-10-14T03:17:51Z 2024-10-14T03:17:51Z 2023 Article 10.35848/1347-4065/aced74 2-s2.0-85170823484 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85170823484&doi=10.35848%2f1347-4065%2faced74&partnerID=40&md5=d930b8744d25fc9fd025aebd63ad1f65 https://irepository.uniten.edu.my/handle/123456789/34070 62 9 92001 Institute of Physics Scopus |
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defect density GZO interface defect perovskite SCAPS-1D Activation energy Conversion efficiency Defect density Electric resistance Electron transport properties Energy gap Gallium compounds II-VI semiconductors Numerical models Perovskite solar cells Transparent conducting oxides Zinc oxide Bandgap graded Charge transport layer Defects density Ga-doped ZnO GZO Inorganics Interface defects Power conversion efficiencies SCAPS-1D Transport layers Perovskite |
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defect density GZO interface defect perovskite SCAPS-1D Activation energy Conversion efficiency Defect density Electric resistance Electron transport properties Energy gap Gallium compounds II-VI semiconductors Numerical models Perovskite solar cells Transparent conducting oxides Zinc oxide Bandgap graded Charge transport layer Defects density Ga-doped ZnO GZO Inorganics Interface defects Power conversion efficiencies SCAPS-1D Transport layers Perovskite Ahmed S. Akhtaruzzaman M. Zulhafizhazuan W. Yusoff Y. Alnaser I.A. Karim M.R. Shahiduzzaman M. Sobayel K. Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell |
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The study encompasses the idea to employ a single bandgap-graded transport layer in lieu of two different (transparent conducting oxide and electron transport layer) layers in the perovskite solar cell to increase the overall device functionality. Numerical simulation has been used to investigate the cell performance parameters. The thickness of the absorber layer has been altered in relation to the defect density to identify the optimal cell parameter values. Maximum power conversion efficiency (PCE) has been recorded as 22.17% at 1E13 cm?3 defect density in the absorber. These findings demonstrate the numerical modeling limitations for the relationship between defect mechanism and performance. The activation energy and effects of series resistance (R s) on solar cells have also been assessed. The temperature degradation gradient of the proposed structure GZO/CsGeI3/NiO/Au has been found to be 3% only with a PCE of 22.17%, which validates the concept of using a bandgap-graded transport layer and paves the way for a new era for perovskite research. � 2023 The Japan Society of Applied Physics. |
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58573844800 |
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58573844800 Ahmed S. Akhtaruzzaman M. Zulhafizhazuan W. Yusoff Y. Alnaser I.A. Karim M.R. Shahiduzzaman M. Sobayel K. |
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Article |
author |
Ahmed S. Akhtaruzzaman M. Zulhafizhazuan W. Yusoff Y. Alnaser I.A. Karim M.R. Shahiduzzaman M. Sobayel K. |
author_sort |
Ahmed S. |
title |
Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell |
title_short |
Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell |
title_full |
Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell |
title_fullStr |
Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell |
title_full_unstemmed |
Theoretical verification of using the Ga-doped ZnO as a charge transport layer in an inorganic perovskite solar cell |
title_sort |
theoretical verification of using the ga-doped zno as a charge transport layer in an inorganic perovskite solar cell |
publisher |
Institute of Physics |
publishDate |
2024 |
_version_ |
1814061040200056832 |
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13.214268 |