Investigation of The Performance Impact of Active Layer Parameter Variations on Inverted Perovskite Solar Cells Using GPVDM

This research explores the performance of inverted perovskite solar cells (IPSC) using the General-purpose Photovoltaic Device Model (GPVDM) software. Alternatively, inorganic p-type semiconductors, especially NiOx which is the most widely used HTL, can provide intrinsically higher stability and exh...

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Main Authors: Aziz, A. M. A., Muniandy, S., Idris, M. I., Napiah, Z. A. F. M., Zamani, Z. B., Norddin, N. B., Rashid, M.
Format: Conference Proceeding
Language:English
Subjects:
Absorption
Fabrication
GPVDM Software
Inverted Perovskite Solar Cells
NiOx
Performance evaluation
Perovskite Solar cells
Photovoltaic cells
Power Conversion Efficiency
Semiconductor device modeling
Simulation
Stability criteria
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creator Aziz, A. M. A.
Muniandy, S.
Idris, M. I.
Napiah, Z. A. F. M.
Zamani, Z. B.
Norddin, N. B.
Rashid, M.
description This research explores the performance of inverted perovskite solar cells (IPSC) using the General-purpose Photovoltaic Device Model (GPVDM) software. Alternatively, inorganic p-type semiconductors, especially NiOx which is the most widely used HTL, can provide intrinsically higher stability and exhibit lower cost than organic polymer-based HTL. The device structure in the simulation comprises ITO/NiOx/MAPbI3/C60/BCP/Ag. Various factors, including layer thickness, electrical parameters, absorption coefficient and refractive index of each layer, can influence the simulated IPSC's performance. GPVDM provides a comprehensive simulation platform to investigate the impact of these factors on the power conversion efficiency (PCE) of IPSCs. The simulation results from GPVDM exhibit a remarkable match and good agreement with achieving efficiencies of 17.35% and 17.57%. To optimize the results, two cases are analyzed and compared. Notably in Case 2, which employs experimental data for α and n from earlier research, outperforms the preceding journal with an efficiency of 18.23% compared to 17.57%. These simulation findings serve as a valuable guide for the fabrication of IPSCs utilizing NiOx, BCP, and C60 as active layers, offering insights into enhancing their performance.
doi_str_mv 10.1109/RSM59033.2023.10326977
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GPVDM provides a comprehensive simulation platform to investigate the impact of these factors on the power conversion efficiency (PCE) of IPSCs. The simulation results from GPVDM exhibit a remarkable match and good agreement with achieving efficiencies of 17.35% and 17.57%. To optimize the results, two cases are analyzed and compared. Notably in Case 2, which employs experimental data for α and n from earlier research, outperforms the preceding journal with an efficiency of 18.23% compared to 17.57%. 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Various factors, including layer thickness, electrical parameters, absorption coefficient and refractive index of each layer, can influence the simulated IPSC's performance. GPVDM provides a comprehensive simulation platform to investigate the impact of these factors on the power conversion efficiency (PCE) of IPSCs. The simulation results from GPVDM exhibit a remarkable match and good agreement with achieving efficiencies of 17.35% and 17.57%. To optimize the results, two cases are analyzed and compared. Notably in Case 2, which employs experimental data for α and n from earlier research, outperforms the preceding journal with an efficiency of 18.23% compared to 17.57%. 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Various factors, including layer thickness, electrical parameters, absorption coefficient and refractive index of each layer, can influence the simulated IPSC's performance. GPVDM provides a comprehensive simulation platform to investigate the impact of these factors on the power conversion efficiency (PCE) of IPSCs. The simulation results from GPVDM exhibit a remarkable match and good agreement with achieving efficiencies of 17.35% and 17.57%. To optimize the results, two cases are analyzed and compared. Notably in Case 2, which employs experimental data for α and n from earlier research, outperforms the preceding journal with an efficiency of 18.23% compared to 17.57%. These simulation findings serve as a valuable guide for the fabrication of IPSCs utilizing NiOx, BCP, and C60 as active layers, offering insights into enhancing their performance.</abstract><pub>IEEE</pub><doi>10.1109/RSM59033.2023.10326977</doi><tpages>4</tpages></addata></record>
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subjects Absorption
Fabrication
GPVDM Software
Inverted Perovskite Solar Cells
NiOx
Performance evaluation
Perovskite Solar cells
Photovoltaic cells
Power Conversion Efficiency
Semiconductor device modeling
Simulation
Stability criteria
title Investigation of The Performance Impact of Active Layer Parameter Variations on Inverted Perovskite Solar Cells Using GPVDM
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