Atomic-layer-deposited Al-doped zinc oxide as a passivating conductive contacting layer for n+-doped surfaces in silicon solar cells

Bart Macco; B.W.H. van de Loo; M. Dielen; D.G.J.A. Loeffen; B.B. van Pelt; Nga Phung; Jimmy Melskens; Marcel A. Verheijen; W.M.M. Kessels

doi:10.1016/j.solmat.2021.111386

Atomic-layer-deposited Al-doped zinc oxide as a passivating conductive contacting layer for n+-doped surfaces in silicon solar cells

Bart Macco (Corresponding author), B.W.H. van de Loo, M. Dielen, D.G.J.A. Loeffen, B.B. van Pelt, Nga Phung, Jimmy Melskens, Marcel A. Verheijen, W.M.M. Kessels

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Abstract

Stacks consisting of an ultrathin SiO2 coated with atomic-layer deposited (ALD) zinc oxide (ZnO) and aluminum oxide (Al2O3) have been shown to yield state-of-the-art passivation of n-type crystalline silicon surfaces. The distinguishing aspect of this novel passivation stack is the very conductive nature of the passivating ZnO layer. In this work, it is demonstrated that such a stack can provide additional functionalities relevant for silicon solar cells. Specifically, it is shown that the conductive and transparent stacks can passivate textured and n+-diffused silicon surfaces and that they can form an Ohmic contact to n+ -diffused surfaces with a low contact resistivity, provided the ZnO is Al-doped. The Al2O3 capping layer has previously been shown to be crucial in the passivation mechanism by preventing the effusion of hydrogen during annealing. Here, it is demonstrated to enable a significant improvement in both the transparency and lateral conductivity of the ZnO upon annealing as well, up to a level typically only attainable by In-based transparent conductive oxides. It is furthermore shown that the passivation of the stacks is thermally stable up to 500–600 oC, depending on the preparation method for the interfacial SiO2. Together, these properties make the presented stack an interesting building block for crystalline silicon solar cells, with possibilities for integration as passivating front contact in Passivated Emitter and Rear Cell (PERC)-like solar cells, e.g. as bottom cell top contact in silicon-perovskite tandem cells, as well as a conductive hydrogenation source for poly-Si passivating contacts.

Original language	English
Article number	111386
Number of pages	13
Journal	Solar Energy Materials and Solar Cells
Volume	233
Early online date	15 Sept 2021
DOIs	https://doi.org/10.1016/j.solmat.2021.111386
Publication status	Published - 1 Dec 2021

Funding

The authors acknowledge J. J. L. M. Meulendijks, C. O. van Bommel, C.A.A. van Helvoirt, J. van Gerwen and J. J. A. Zeebregts for their technical support. The authors gratefully acknowledge Solliance for funding the TEM facility and dr. B. Barcones-Campo for the TEM sample preparation. The authors acknowledge the project partners TNO and Tempress Systems, and especially dr. L.J. Geerligs of TNO for providing the LPCVD poly-Si samples. We acknowledge financial support for this research from the Top consortia for Knowledge and Innovation (TKI) Solar Energy program “PERCspective” (TEUE119005) and “SATURNIA” (TEUE118002) of the Ministry of Economic Affairs of The Netherlands. The work of B. Macco and J. Melskens was supported by The Netherlands Organization for Scientific Research under the Dutch TTW-VENI Grants 16775 and 15896, respectively. The authors acknowledge J. J. L. M. Meulendijks, C. O. van Bommel, C.A.A. van Helvoirt, J. van Gerwen and J. J. A. Zeebregts for their technical support.. The authors gratefully acknowledge Solliance for funding the TEM facility and dr. B. Barcones-Campo for the TEM sample preparation. The authors acknowledge the project partners TNO and Tempress Systems, and especially dr. L.J. Geerligs of TNO for providing the LPCVD poly-Si samples. We acknowledge financial support for this research from the Top consortia for Knowledge and Innovation (TKI) Solar Energy program “PERCspective” (TEUE119005) and “SATURNIA” (TEUE118002) of the Ministry of Economic Affairs of The Netherlands. The work of B. Macco and J. Melskens was supported by The Netherlands Organization for Scientific Research under the Dutch TTW-VENI Grants 16775 and 15896 , respectively.

Funders	Funder number
Top consortia for Knowledge and Innovation	TEUE119005, TEUE118002
Ministerie van Economische Zaken en Klimaat
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	15896, 16775

Keywords

Atomic layer deposition
Crystalline silicon solar cells
Passivating contact
Surface passivation
Transparent conductive oxide

UN SDGs

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

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10.1016/j.solmat.2021.111386

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Macco, B., van de Loo, B. W. H., Dielen, M., Loeffen, D. G. J. A., van Pelt, B. B., Phung, N., Melskens, J., Verheijen, M. A., & Kessels, W. M. M. (2021). Atomic-layer-deposited Al-doped zinc oxide as a passivating conductive contacting layer for n+-doped surfaces in silicon solar cells. Solar Energy Materials and Solar Cells, 233, Article 111386. https://doi.org/10.1016/j.solmat.2021.111386

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title = "Atomic-layer-deposited Al-doped zinc oxide as a passivating conductive contacting layer for n+-doped surfaces in silicon solar cells",

abstract = "Stacks consisting of an ultrathin SiO2 coated with atomic-layer deposited (ALD) zinc oxide (ZnO) and aluminum oxide (Al2O3) have been shown to yield state-of-the-art passivation of n-type crystalline silicon surfaces. The distinguishing aspect of this novel passivation stack is the very conductive nature of the passivating ZnO layer. In this work, it is demonstrated that such a stack can provide additional functionalities relevant for silicon solar cells. Specifically, it is shown that the conductive and transparent stacks can passivate textured and n+-diffused silicon surfaces and that they can form an Ohmic contact to n+ -diffused surfaces with a low contact resistivity, provided the ZnO is Al-doped. The Al2O3 capping layer has previously been shown to be crucial in the passivation mechanism by preventing the effusion of hydrogen during annealing. Here, it is demonstrated to enable a significant improvement in both the transparency and lateral conductivity of the ZnO upon annealing as well, up to a level typically only attainable by In-based transparent conductive oxides. It is furthermore shown that the passivation of the stacks is thermally stable up to 500–600 oC, depending on the preparation method for the interfacial SiO2. Together, these properties make the presented stack an interesting building block for crystalline silicon solar cells, with possibilities for integration as passivating front contact in Passivated Emitter and Rear Cell (PERC)-like solar cells, e.g. as bottom cell top contact in silicon-perovskite tandem cells, as well as a conductive hydrogenation source for poly-Si passivating contacts.",

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AU - Macco, Bart

AU - van de Loo, B.W.H.

AU - Dielen, M.

AU - Loeffen, D.G.J.A.

AU - van Pelt, B.B.

AU - Phung, Nga

AU - Melskens, Jimmy

AU - Verheijen, Marcel A.

AU - Kessels, W.M.M.

PY - 2021/12/1

Y1 - 2021/12/1

N2 - Stacks consisting of an ultrathin SiO2 coated with atomic-layer deposited (ALD) zinc oxide (ZnO) and aluminum oxide (Al2O3) have been shown to yield state-of-the-art passivation of n-type crystalline silicon surfaces. The distinguishing aspect of this novel passivation stack is the very conductive nature of the passivating ZnO layer. In this work, it is demonstrated that such a stack can provide additional functionalities relevant for silicon solar cells. Specifically, it is shown that the conductive and transparent stacks can passivate textured and n+-diffused silicon surfaces and that they can form an Ohmic contact to n+ -diffused surfaces with a low contact resistivity, provided the ZnO is Al-doped. The Al2O3 capping layer has previously been shown to be crucial in the passivation mechanism by preventing the effusion of hydrogen during annealing. Here, it is demonstrated to enable a significant improvement in both the transparency and lateral conductivity of the ZnO upon annealing as well, up to a level typically only attainable by In-based transparent conductive oxides. It is furthermore shown that the passivation of the stacks is thermally stable up to 500–600 oC, depending on the preparation method for the interfacial SiO2. Together, these properties make the presented stack an interesting building block for crystalline silicon solar cells, with possibilities for integration as passivating front contact in Passivated Emitter and Rear Cell (PERC)-like solar cells, e.g. as bottom cell top contact in silicon-perovskite tandem cells, as well as a conductive hydrogenation source for poly-Si passivating contacts.

AB - Stacks consisting of an ultrathin SiO2 coated with atomic-layer deposited (ALD) zinc oxide (ZnO) and aluminum oxide (Al2O3) have been shown to yield state-of-the-art passivation of n-type crystalline silicon surfaces. The distinguishing aspect of this novel passivation stack is the very conductive nature of the passivating ZnO layer. In this work, it is demonstrated that such a stack can provide additional functionalities relevant for silicon solar cells. Specifically, it is shown that the conductive and transparent stacks can passivate textured and n+-diffused silicon surfaces and that they can form an Ohmic contact to n+ -diffused surfaces with a low contact resistivity, provided the ZnO is Al-doped. The Al2O3 capping layer has previously been shown to be crucial in the passivation mechanism by preventing the effusion of hydrogen during annealing. Here, it is demonstrated to enable a significant improvement in both the transparency and lateral conductivity of the ZnO upon annealing as well, up to a level typically only attainable by In-based transparent conductive oxides. It is furthermore shown that the passivation of the stacks is thermally stable up to 500–600 oC, depending on the preparation method for the interfacial SiO2. Together, these properties make the presented stack an interesting building block for crystalline silicon solar cells, with possibilities for integration as passivating front contact in Passivated Emitter and Rear Cell (PERC)-like solar cells, e.g. as bottom cell top contact in silicon-perovskite tandem cells, as well as a conductive hydrogenation source for poly-Si passivating contacts.

KW - Atomic layer deposition

KW - Crystalline silicon solar cells

KW - Passivating contact

KW - Surface passivation

KW - Transparent conductive oxide

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DO - 10.1016/j.solmat.2021.111386

M3 - Article

SN - 0927-0248

VL - 233

JO - Solar Energy Materials and Solar Cells

JF - Solar Energy Materials and Solar Cells

M1 - 111386

ER -

Atomic-layer-deposited Al-doped zinc oxide as a passivating conductive contacting layer for n+-doped surfaces in silicon solar cells

Abstract

Funding

Keywords

UN SDGs

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