Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells

For human society, all activities require energy support. Solar cells are a means of converting solar energy into electrical energy using the photovoltaic effect of semiconductor materials. This photoelectric absorber layer has been developed for more than 70 years. Currently, the layered solar pane...

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Main Authors: Shuaijie Wang, Dong Zhang, Zhenhe Ju
Format: Article
Language:English
Published: Wiley 2022-01-01
Series:Advances in Materials Science and Engineering
Online Access:http://dx.doi.org/10.1155/2022/5862204
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author Shuaijie Wang
Dong Zhang
Zhenhe Ju
author_facet Shuaijie Wang
Dong Zhang
Zhenhe Ju
author_sort Shuaijie Wang
collection DOAJ
description For human society, all activities require energy support. Solar cells are a means of converting solar energy into electrical energy using the photovoltaic effect of semiconductor materials. This photoelectric absorber layer has been developed for more than 70 years. Currently, the layered solar panel industry has achieved an energy conversion efficiency of 47%. In addition to efficiency, the cost of solar cells has been optimized, and the cost of commercial silicon solar cells has been greatly reduced. There is an urgent need for energy transfer research through the solar cell interface. Many researchers are studying and discovering new elements in this field. On this basis, the transmission ion interface of ultra-thin in-amplified quantum solar cell panels was studied, and very effective conclusions were drawn on the basis of experimental preparation and analysis.
format Article
id doaj-art-84d025b723bd4cbd8d6c674a8049c580
institution Kabale University
issn 1687-8442
language English
publishDate 2022-01-01
publisher Wiley
record_format Article
series Advances in Materials Science and Engineering
spelling doaj-art-84d025b723bd4cbd8d6c674a8049c5802025-02-03T01:07:35ZengWileyAdvances in Materials Science and Engineering1687-84422022-01-01202210.1155/2022/5862204Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar CellsShuaijie Wang0Dong Zhang1Zhenhe Ju2School of Renewable EnergySchool of Renewable EnergySchool of Renewable EnergyFor human society, all activities require energy support. Solar cells are a means of converting solar energy into electrical energy using the photovoltaic effect of semiconductor materials. This photoelectric absorber layer has been developed for more than 70 years. Currently, the layered solar panel industry has achieved an energy conversion efficiency of 47%. In addition to efficiency, the cost of solar cells has been optimized, and the cost of commercial silicon solar cells has been greatly reduced. There is an urgent need for energy transfer research through the solar cell interface. Many researchers are studying and discovering new elements in this field. On this basis, the transmission ion interface of ultra-thin in-amplified quantum solar cell panels was studied, and very effective conclusions were drawn on the basis of experimental preparation and analysis.http://dx.doi.org/10.1155/2022/5862204
spellingShingle Shuaijie Wang
Dong Zhang
Zhenhe Ju
Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells
Advances in Materials Science and Engineering
title Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells
title_full Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells
title_fullStr Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells
title_full_unstemmed Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells
title_short Interfacial Transport Study of Ultra-Thin InN-Enhanced Quantum Dot Solar Cells
title_sort interfacial transport study of ultra thin inn enhanced quantum dot solar cells
url http://dx.doi.org/10.1155/2022/5862204
work_keys_str_mv AT shuaijiewang interfacialtransportstudyofultrathininnenhancedquantumdotsolarcells
AT dongzhang interfacialtransportstudyofultrathininnenhancedquantumdotsolarcells
AT zhenheju interfacialtransportstudyofultrathininnenhancedquantumdotsolarcells