Origins of hydrogen that passivates bulk defects in silicon heterojunction solar cells

Chang Sun; William Weigand; Jianwei Shi; Zhengshan Yu; Rabin Basnet; Sieu Pheng Phang; Zachary C. Holman; Daniel Maconald

doi:10.1063/1.5132368

Origins of hydrogen that passivates bulk defects in silicon heterojunction solar cells

Chang Sun^*, William Weigand, Jianwei Shi, Zhengshan Yu, Rabin Basnet, Sieu Pheng Phang, Zachary C. Holman, Daniel Maconald

^*Corresponding author for this work

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

10 Citations (Scopus)

Abstract

Silicon heterojunction solar cell fabrication incorporates a significant amount of hydrogen into the silicon wafer bulk, and the amount of injected hydrogen is comparable to that introduced by silicon nitride films during a high-temperature firing step. In this work, the origins of the hydrogen injected during heterojunction cell processing have been identified. We demonstrate that the hydrogen plasma treatment that is routinely included to improve surface passivation considerably increases the hydrogen concentration in the wafers. We also show that the hydrogenated amorphous silicon i/p⁺ stack is more effective than the i/n⁺ stack for bulk hydrogen incorporation, and both are more effective than intrinsic films alone.

Original language	English
Journal	Applied Physics Letters
Volume	115
Issue number	25
DOIs	https://doi.org/10.1063/1.5132368
Publication status	Published - 16 Dec 2019

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title = "Origins of hydrogen that passivates bulk defects in silicon heterojunction solar cells",

abstract = "Silicon heterojunction solar cell fabrication incorporates a significant amount of hydrogen into the silicon wafer bulk, and the amount of injected hydrogen is comparable to that introduced by silicon nitride films during a high-temperature firing step. In this work, the origins of the hydrogen injected during heterojunction cell processing have been identified. We demonstrate that the hydrogen plasma treatment that is routinely included to improve surface passivation considerably increases the hydrogen concentration in the wafers. We also show that the hydrogenated amorphous silicon i/p+ stack is more effective than the i/n+ stack for bulk hydrogen incorporation, and both are more effective than intrinsic films alone.",

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AU - Sun, Chang

AU - Weigand, William

AU - Shi, Jianwei

AU - Yu, Zhengshan

AU - Basnet, Rabin

AU - Phang, Sieu Pheng

AU - Holman, Zachary C.

AU - Maconald, Daniel

PY - 2019/12/16

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N2 - Silicon heterojunction solar cell fabrication incorporates a significant amount of hydrogen into the silicon wafer bulk, and the amount of injected hydrogen is comparable to that introduced by silicon nitride films during a high-temperature firing step. In this work, the origins of the hydrogen injected during heterojunction cell processing have been identified. We demonstrate that the hydrogen plasma treatment that is routinely included to improve surface passivation considerably increases the hydrogen concentration in the wafers. We also show that the hydrogenated amorphous silicon i/p+ stack is more effective than the i/n+ stack for bulk hydrogen incorporation, and both are more effective than intrinsic films alone.

AB - Silicon heterojunction solar cell fabrication incorporates a significant amount of hydrogen into the silicon wafer bulk, and the amount of injected hydrogen is comparable to that introduced by silicon nitride films during a high-temperature firing step. In this work, the origins of the hydrogen injected during heterojunction cell processing have been identified. We demonstrate that the hydrogen plasma treatment that is routinely included to improve surface passivation considerably increases the hydrogen concentration in the wafers. We also show that the hydrogenated amorphous silicon i/p+ stack is more effective than the i/n+ stack for bulk hydrogen incorporation, and both are more effective than intrinsic films alone.

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Origins of hydrogen that passivates bulk defects in silicon heterojunction solar cells

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