High-Efficient Solar Cells Textured by Cu/Ag-Cocatalyzed Chemical Etching on Diamond Wire Sawing Multicrystalline Silicon

Wei Chen; Yaoping Liu; Juntao Wu; Quansheng Chen; Yan Zhao; Yan Wang; Xiaolong Du

doi:10.1021/acsami.9b00724

High-Efficient Solar Cells Textured by Cu/Ag-Cocatalyzed Chemical Etching on Diamond Wire Sawing Multicrystalline Silicon

Wei Chen, Yaoping Liu, Juntao Wu, Quansheng Chen, Yan Zhao, Yan Wang, Xiaolong Du

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

We reported a novel texture method through one-step Cu/Ag-cocatalyzed chemical etching which can be widely used in the photovoltaic industry because of its simple and low-cost process. The etching mechanism of an inverted rectangular pyramid is the cooperation of Ag-catalyzed vertical etching and Cu-catalyzed lateral etching. In our texture method, neither saw damage removal nor post-treatment is needed. During the etching process, the digging holes by Ag-catalyzed etching and enlarging holes by Cu-catalyzed etching completed at the same step. Benefiting from the excellent light-trapping and passivation effect of the inverted rectangular pyramid, diamond wire sawing multicrystalline silicon (mc-Si) Al-BSF solar cells with a super high efficiency of 19.49% had been obtained.

Original language	English
Pages (from-to)	10052-10058
Number of pages	7
Journal	ACS Applied Materials and Interfaces
Volume	11
Issue number	10
DOIs	https://doi.org/10.1021/acsami.9b00724
State	Published - Mar 13 2019
Externally published	Yes

Keywords

Cu/Ag-cocatalyzed chemical etching
diamond wire sawing
inverted rectangular pyramid
metal-catalyzed chemical etching
silicon solar cells

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10.1021/acsami.9b00724

Cite this

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title = "High-Efficient Solar Cells Textured by Cu/Ag-Cocatalyzed Chemical Etching on Diamond Wire Sawing Multicrystalline Silicon",

abstract = "We reported a novel texture method through one-step Cu/Ag-cocatalyzed chemical etching which can be widely used in the photovoltaic industry because of its simple and low-cost process. The etching mechanism of an inverted rectangular pyramid is the cooperation of Ag-catalyzed vertical etching and Cu-catalyzed lateral etching. In our texture method, neither saw damage removal nor post-treatment is needed. During the etching process, the digging holes by Ag-catalyzed etching and enlarging holes by Cu-catalyzed etching completed at the same step. Benefiting from the excellent light-trapping and passivation effect of the inverted rectangular pyramid, diamond wire sawing multicrystalline silicon (mc-Si) Al-BSF solar cells with a super high efficiency of 19.49% had been obtained.",

keywords = "Cu/Ag-cocatalyzed chemical etching, diamond wire sawing, inverted rectangular pyramid, metal-catalyzed chemical etching, silicon solar cells",

author = "Wei Chen and Yaoping Liu and Juntao Wu and Quansheng Chen and Yan Zhao and Yan Wang and Xiaolong Du",

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AU - Chen, Wei

AU - Liu, Yaoping

AU - Wu, Juntao

AU - Chen, Quansheng

AU - Zhao, Yan

AU - Wang, Yan

AU - Du, Xiaolong

PY - 2019/3/13

Y1 - 2019/3/13

N2 - We reported a novel texture method through one-step Cu/Ag-cocatalyzed chemical etching which can be widely used in the photovoltaic industry because of its simple and low-cost process. The etching mechanism of an inverted rectangular pyramid is the cooperation of Ag-catalyzed vertical etching and Cu-catalyzed lateral etching. In our texture method, neither saw damage removal nor post-treatment is needed. During the etching process, the digging holes by Ag-catalyzed etching and enlarging holes by Cu-catalyzed etching completed at the same step. Benefiting from the excellent light-trapping and passivation effect of the inverted rectangular pyramid, diamond wire sawing multicrystalline silicon (mc-Si) Al-BSF solar cells with a super high efficiency of 19.49% had been obtained.

AB - We reported a novel texture method through one-step Cu/Ag-cocatalyzed chemical etching which can be widely used in the photovoltaic industry because of its simple and low-cost process. The etching mechanism of an inverted rectangular pyramid is the cooperation of Ag-catalyzed vertical etching and Cu-catalyzed lateral etching. In our texture method, neither saw damage removal nor post-treatment is needed. During the etching process, the digging holes by Ag-catalyzed etching and enlarging holes by Cu-catalyzed etching completed at the same step. Benefiting from the excellent light-trapping and passivation effect of the inverted rectangular pyramid, diamond wire sawing multicrystalline silicon (mc-Si) Al-BSF solar cells with a super high efficiency of 19.49% had been obtained.

KW - Cu/Ag-cocatalyzed chemical etching

KW - diamond wire sawing

KW - inverted rectangular pyramid

KW - metal-catalyzed chemical etching

KW - silicon solar cells

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ER -

High-Efficient Solar Cells Textured by Cu/Ag-Cocatalyzed Chemical Etching on Diamond Wire Sawing Multicrystalline Silicon

Abstract

Keywords

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