Microcavity-Enhanced Light-Trapping for Highly Efficient Organic Parallel Tandem Solar Cells

A high‐performance parallel tandem solar cell employing ultra‐thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front sub‐cell and a microcavity assisted back sub‐cell. In addition to the extended optical field as a result of the tandem architecture, the prominent...

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Published in	Advanced materials (Weinheim) Vol. 26; no. 39; pp. 6778 - 6784
Main Authors	Zuo, Lijian, Chueh, Chu-Chen, Xu, Yun-Xiang, Chen, Kung-Shih, Zang, Yue, Li, Chang-Zhi, Chen, Hongzheng, Jen, Alex K.-Y.
Format	Journal Article
Language	English
Published	Germany Blackwell Publishing Ltd 22.10.2014
Subjects	Architecture efficient light absorption micro-cavity effect Microcavities Organic materials organic photovoltaics parallel tandem solar cells Photovoltaic cells semitransparent electrode Silver Solar cells Tandem configuration Utilization micro-cavity effect parallel tandem solar cells efficient light absorption semitransparent electrode organic photovoltaics
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Abstract	A high‐performance parallel tandem solar cell employing ultra‐thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front sub‐cell and a microcavity assisted back sub‐cell. In addition to the extended optical field as a result of the tandem architecture, the prominent microcavity resonance formed in the back sub‐cell enables such a parallel tandem configuration to possess high light utilization efficiency (the peak EQE value is over 80%) and a high photovoltaic performance of 9.2%. This study establishes an effective architecture that can be generally applicable to all organic materials for improving their performance.
AbstractList	A high‐performance parallel tandem solar cell employing ultra‐thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front sub‐cell and a microcavity assisted back sub‐cell. In addition to the extended optical field as a result of the tandem architecture, the prominent microcavity resonance formed in the back sub‐cell enables such a parallel tandem configuration to possess high light utilization efficiency (the peak EQE value is over 80%) and a high photovoltaic performance of 9.2%. This study establishes an effective architecture that can be generally applicable to all organic materials for improving their performance. A high-performance parallel tandem solar cell employing ultra-thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front sub-cell and a microcavity assisted back sub-cell. In addition to the extended optical field as a result of the tandem architecture, the prominent microcavity resonance formed in the back sub-cell enables such a parallel tandem configuration to possess high light utilization efficiency (the peak EQE value is over 80%) and a high photovoltaic performance of 9.2%. This study establishes an effective architecture that can be generally applicable to all organic materials for improving their performance.A high-performance parallel tandem solar cell employing ultra-thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front sub-cell and a microcavity assisted back sub-cell. In addition to the extended optical field as a result of the tandem architecture, the prominent microcavity resonance formed in the back sub-cell enables such a parallel tandem configuration to possess high light utilization efficiency (the peak EQE value is over 80%) and a high photovoltaic performance of 9.2%. This study establishes an effective architecture that can be generally applicable to all organic materials for improving their performance.
Author	Xu, Yun-Xiang Jen, Alex K.-Y. Li, Chang-Zhi Zang, Yue Zuo, Lijian Chen, Hongzheng Chueh, Chu-Chen Chen, Kung-Shih
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Snippet	A high‐performance parallel tandem solar cell employing ultra‐thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front... A high-performance parallel tandem solar cell employing ultra-thin Ag as the intermediate anode is demonstrated, which comprises a semitransparent front...
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SubjectTerms	Architecture efficient light absorption micro-cavity effect Microcavities Organic materials organic photovoltaics parallel tandem solar cells Photovoltaic cells semitransparent electrode Silver Solar cells Tandem configuration Utilization
Title	Microcavity-Enhanced Light-Trapping for Highly Efficient Organic Parallel Tandem Solar Cells
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