Impact of PECVD μc-Si:H deposition on tunnel oxide for passivating contacts

Anatole Desthieux; Jorge Posada; Pierre Philippe Grand; Cédric Broussillou; Barbara Bazer-Bachi; Gilles Goaer; Davina Messou; Muriel Bouttemy; Etienne Drahi; Pere Roca I Cabarrocas

doi:10.1051/epjpv/2020001

Impact of PECVD μc-Si:H deposition on tunnel oxide for passivating contacts

Anatole Desthieux
, Jorge Posada
, Pierre Philippe Grand
, Cédric Broussillou
, Barbara Bazer-Bachi
, Gilles Goaer
, Davina Messou
, Muriel Bouttemy
, Etienne Drahi
, Pere Roca I Cabarrocas

Lamsid/EDF/R and D
Institut Photovoltaïque d'Ile-de-France
Institut polytechnique de Paris
Photowatt International
Université Versailles-Saint Quentin
Total

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

Abstract

Passivating contacts are becoming a mainstream option in current photovoltaic industry due to their ability to provide an outstanding surface passivation along with a good conductivity for carrier collection. However, their integration usually requires long annealing steps which are not desirable in industry. In this work we study PECVD as a way to carry out all deposition steps: silicon oxide (SiOx), doped polycrystalline silicon (poly-Si) and silicon nitride (SiNx:H), followed by a single firing step. Blistering of the poly-Si layer has been avoided by depositing (p+) microcrystalline silicon (μc-Si:H). We report on the impact of this deposition step on the SiOx layer deposited by PECVD, and on the passivation properties by comparing PECVD and wet-chemical oxide in this hole-selective passivating contact stack. We have reached iVoc > 690 mV on p-type FZ wafers for wet-chemical SiOx\(p+) μc-Si\SiNx:H with no annealing step.

Original language	English
Article number	11
Journal	EPJ Photovoltaics
Volume	11
DOIs	https://doi.org/10.1051/epjpv/2020001
Publication status	Published - 1 Jan 2020

UN SDGs

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

SDG 7 Affordable and Clean Energy

Keywords

Cast-mono
PECVD
Passivating contact
Passivation
Silicon oxide
Silicon solar cell
XPS
μc-Si:H

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10.1051/epjpv/2020001

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title = "Impact of PECVD μc-Si:H deposition on tunnel oxide for passivating contacts",

abstract = "Passivating contacts are becoming a mainstream option in current photovoltaic industry due to their ability to provide an outstanding surface passivation along with a good conductivity for carrier collection. However, their integration usually requires long annealing steps which are not desirable in industry. In this work we study PECVD as a way to carry out all deposition steps: silicon oxide (SiOx), doped polycrystalline silicon (poly-Si) and silicon nitride (SiNx:H), followed by a single firing step. Blistering of the poly-Si layer has been avoided by depositing (p+) microcrystalline silicon (μc-Si:H). We report on the impact of this deposition step on the SiOx layer deposited by PECVD, and on the passivation properties by comparing PECVD and wet-chemical oxide in this hole-selective passivating contact stack. We have reached iVoc > 690 mV on p-type FZ wafers for wet-chemical SiOx\textbackslash{}(p+) μc-Si\textbackslash{}SiNx:H with no annealing step.",

keywords = "Cast-mono, PECVD, Passivating contact, Passivation, Silicon oxide, Silicon solar cell, XPS, μc-Si:H",

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AU - Desthieux, Anatole

AU - Posada, Jorge

AU - Grand, Pierre Philippe

AU - Broussillou, Cédric

AU - Bazer-Bachi, Barbara

AU - Goaer, Gilles

AU - Messou, Davina

AU - Bouttemy, Muriel

AU - Drahi, Etienne

AU - Roca I Cabarrocas, Pere

PY - 2020/1/1

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N2 - Passivating contacts are becoming a mainstream option in current photovoltaic industry due to their ability to provide an outstanding surface passivation along with a good conductivity for carrier collection. However, their integration usually requires long annealing steps which are not desirable in industry. In this work we study PECVD as a way to carry out all deposition steps: silicon oxide (SiOx), doped polycrystalline silicon (poly-Si) and silicon nitride (SiNx:H), followed by a single firing step. Blistering of the poly-Si layer has been avoided by depositing (p+) microcrystalline silicon (μc-Si:H). We report on the impact of this deposition step on the SiOx layer deposited by PECVD, and on the passivation properties by comparing PECVD and wet-chemical oxide in this hole-selective passivating contact stack. We have reached iVoc > 690 mV on p-type FZ wafers for wet-chemical SiOx\(p+) μc-Si\SiNx:H with no annealing step.

AB - Passivating contacts are becoming a mainstream option in current photovoltaic industry due to their ability to provide an outstanding surface passivation along with a good conductivity for carrier collection. However, their integration usually requires long annealing steps which are not desirable in industry. In this work we study PECVD as a way to carry out all deposition steps: silicon oxide (SiOx), doped polycrystalline silicon (poly-Si) and silicon nitride (SiNx:H), followed by a single firing step. Blistering of the poly-Si layer has been avoided by depositing (p+) microcrystalline silicon (μc-Si:H). We report on the impact of this deposition step on the SiOx layer deposited by PECVD, and on the passivation properties by comparing PECVD and wet-chemical oxide in this hole-selective passivating contact stack. We have reached iVoc > 690 mV on p-type FZ wafers for wet-chemical SiOx\(p+) μc-Si\SiNx:H with no annealing step.

KW - Cast-mono

KW - PECVD

KW - Passivating contact

KW - Passivation

KW - Silicon oxide

KW - Silicon solar cell

KW - XPS

KW - μc-Si:H

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DO - 10.1051/epjpv/2020001

M3 - Article

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JF - EPJ Photovoltaics

M1 - 11

ER -

Impact of PECVD μc-Si:H deposition on tunnel oxide for passivating contacts

Abstract

UN SDGs

Keywords

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