Gapless point back surface field for the counter doping of large-area interdigitated back contact solar cells using a blanket shadow mask implantation process

Young Su Kim; Chanbin Mo; Doo Youl Lee; Sung Chan Park; Dongseop Kim; Junggyu Nam; Jung Yup Yang; Dongchul Suh; Hyun Jong Kim; Hyomin Park; Se Jin Park; Donghwan Kim; Jungho Song; Hae Seok Lee; Sungeun Park; Yoonmook Kang

doi:10.1002/pip.2910

Gapless point back surface field for the counter doping of large-area interdigitated back contact solar cells using a blanket shadow mask implantation process

Young Su Kim, Chanbin Mo, Doo Youl Lee, Sung Chan Park, Dongseop Kim, Junggyu Nam, Jung Yup Yang, Dongchul Suh, Hyun Jong Kim, Hyomin Park, Se Jin Park, Donghwan Kim, Jungho Song, Hae Seok Lee, Sungeun Park, Yoonmook Kang

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

5 Citations (Scopus)

Abstract

Gapless interdigitated back contact (IBC) solar cells were fabricated with phosphorous back surface field on a boron emitter, using an ion implantation process. Boron emitter (boron ion implantation) is counter doped by the phosphorus back surface field (BSF) (phosphorus ion implantation) without gap. The gapless process step between the emitter and BSF was compared to existing IBC solar cell with gaps between emitters and BSFs obtained using diffusion processes. We optimized the doping process in the phosphorous BSF and boron emitter region, and the implied V_oc and contact resistance relationship of the phosphorous and boron implantation dose in the counter doped region was analyzed. We confirmed the shunt resistance of the gapless IBC solar cells and the possibility of shunt behavior in gapless IBC solar cells. The highly doped counter doped BSF led to a controlled junction breakdown at high reverse bias voltages of around 7.5 V. After the doping region was optimized with the counter doped BSF and emitter, a large-area (5 inch pseudo square) gapless IBC solar cell with a power conversion efficiency of 22.9% was made.

Original language	English
Pages (from-to)	989-995
Number of pages	7
Journal	Progress in Photovoltaics: Research and Applications
Volume	25
Issue number	12
DOIs	https://doi.org/10.1002/pip.2910
Publication status	Published - 2017 Dec

Bibliographical note

Publisher Copyright:
Copyright © 2017 John Wiley & Sons, Ltd.

Keywords

IBC solar cells
counter doping
gapless doping
ion implantation

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Renewable Energy, Sustainability and the Environment
Condensed Matter Physics
Electrical and Electronic Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/pip.2910

Cite this

Kim, Y. S., Mo, C., Lee, D. Y., Park, S. C., Kim, D., Nam, J., Yang, J. Y., Suh, D., Kim, H. J., Park, H., Park, S. J., Kim, D., Song, J., Lee, H. S., Park, S., & Kang, Y. (2017). Gapless point back surface field for the counter doping of large-area interdigitated back contact solar cells using a blanket shadow mask implantation process. Progress in Photovoltaics: Research and Applications, 25(12), 989-995. https://doi.org/10.1002/pip.2910

Gapless point back surface field for the counter doping of large-area interdigitated back contact solar cells using a blanket shadow mask implantation process. / Kim, Young Su; Mo, Chanbin; Lee, Doo Youl et al.
In: Progress in Photovoltaics: Research and Applications, Vol. 25, No. 12, 12.2017, p. 989-995.

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

Kim, YS, Mo, C, Lee, DY, Park, SC, Kim, D, Nam, J, Yang, JY, Suh, D, Kim, HJ, Park, H, Park, SJ, Kim, D, Song, J, Lee, HS, Park, S & Kang, Y 2017, 'Gapless point back surface field for the counter doping of large-area interdigitated back contact solar cells using a blanket shadow mask implantation process', Progress in Photovoltaics: Research and Applications, vol. 25, no. 12, pp. 989-995. https://doi.org/10.1002/pip.2910

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abstract = "Gapless interdigitated back contact (IBC) solar cells were fabricated with phosphorous back surface field on a boron emitter, using an ion implantation process. Boron emitter (boron ion implantation) is counter doped by the phosphorus back surface field (BSF) (phosphorus ion implantation) without gap. The gapless process step between the emitter and BSF was compared to existing IBC solar cell with gaps between emitters and BSFs obtained using diffusion processes. We optimized the doping process in the phosphorous BSF and boron emitter region, and the implied Voc and contact resistance relationship of the phosphorous and boron implantation dose in the counter doped region was analyzed. We confirmed the shunt resistance of the gapless IBC solar cells and the possibility of shunt behavior in gapless IBC solar cells. The highly doped counter doped BSF led to a controlled junction breakdown at high reverse bias voltages of around 7.5 V. After the doping region was optimized with the counter doped BSF and emitter, a large-area (5 inch pseudo square) gapless IBC solar cell with a power conversion efficiency of 22.9% was made.",

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AU - Kim, Young Su

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AU - Lee, Doo Youl

AU - Park, Sung Chan

AU - Kim, Dongseop

AU - Nam, Junggyu

AU - Yang, Jung Yup

AU - Suh, Dongchul

AU - Kim, Hyun Jong

AU - Park, Hyomin

AU - Park, Se Jin

AU - Kim, Donghwan

AU - Song, Jungho

AU - Lee, Hae Seok

AU - Park, Sungeun

AU - Kang, Yoonmook

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N2 - Gapless interdigitated back contact (IBC) solar cells were fabricated with phosphorous back surface field on a boron emitter, using an ion implantation process. Boron emitter (boron ion implantation) is counter doped by the phosphorus back surface field (BSF) (phosphorus ion implantation) without gap. The gapless process step between the emitter and BSF was compared to existing IBC solar cell with gaps between emitters and BSFs obtained using diffusion processes. We optimized the doping process in the phosphorous BSF and boron emitter region, and the implied Voc and contact resistance relationship of the phosphorous and boron implantation dose in the counter doped region was analyzed. We confirmed the shunt resistance of the gapless IBC solar cells and the possibility of shunt behavior in gapless IBC solar cells. The highly doped counter doped BSF led to a controlled junction breakdown at high reverse bias voltages of around 7.5 V. After the doping region was optimized with the counter doped BSF and emitter, a large-area (5 inch pseudo square) gapless IBC solar cell with a power conversion efficiency of 22.9% was made.

AB - Gapless interdigitated back contact (IBC) solar cells were fabricated with phosphorous back surface field on a boron emitter, using an ion implantation process. Boron emitter (boron ion implantation) is counter doped by the phosphorus back surface field (BSF) (phosphorus ion implantation) without gap. The gapless process step between the emitter and BSF was compared to existing IBC solar cell with gaps between emitters and BSFs obtained using diffusion processes. We optimized the doping process in the phosphorous BSF and boron emitter region, and the implied Voc and contact resistance relationship of the phosphorous and boron implantation dose in the counter doped region was analyzed. We confirmed the shunt resistance of the gapless IBC solar cells and the possibility of shunt behavior in gapless IBC solar cells. The highly doped counter doped BSF led to a controlled junction breakdown at high reverse bias voltages of around 7.5 V. After the doping region was optimized with the counter doped BSF and emitter, a large-area (5 inch pseudo square) gapless IBC solar cell with a power conversion efficiency of 22.9% was made.

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Gapless point back surface field for the counter doping of large-area interdigitated back contact solar cells using a blanket shadow mask implantation process

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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