Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell

Jingxiang Xu; Yuji Higuchi; Nobuki Ozawa; Momoji Kubo

doi:10.1149/06801.3187ecst

Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell

Jingxiang Xu, Yuji Higuchi, Nobuki Ozawa, Momoji Kubo

Tohoku University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

4 Citations (Scopus)

Abstract

Sintering of Ni particles in the Ni/Y-doped ZrO₂ anode is a major obstacle to the widespread use of solid oxide fuel cell. In this study, we investigated the dopant effect on the diffusion of a Ni atom on the ZrO₂ surface with dopants (Y and Al) by density functional theory calculations in order to inhibit the sintering. The most stable adsorption sites of the Ni atom on the Al-doped and Y-doped ZrO₂ surfaces are the vicinity of the twofold-coordination oxygen atom and the vicinity of an oxygen vacancy, respectively. It is found that the most stable adsorption energy on the Al-doped ZrO₂ surface is larger than that on the Y-doped ZrO₂ surface. The analysis of diffusion path based on the potential energy surfaces of the Ni atom on the two surfaces shows that the energy barrier for the diffusion of the Ni atom on the Al-doped ZrO₂ surface is larger than that on the Y-doped ZrO₂ surface. The diffusion of the Ni atom on the Al-doped ZrO₂ surface is more difficult than that on the Y-doped ZrO₂ surface. This is because the Ni atom strongly bound to the twofold-coordination oxygen atom and the Ni atom is constrained in the Al-doped ZrO₂ surface. Thus, the Ni sintering on the Al-doped ZrO₂ surface is inhibited compared to that on the Y-doped ZrO₂ surface.

Original language	English
Title of host publication	Solid Oxide Fuel Cells 14, SOFC 2015
Editors	K. Eguchi, S. C. Singhal
Publisher	Electrochemical Society Inc.
Pages	3187-3193
Number of pages	7
Edition	1
ISBN (Electronic)	9781607685395
DOIs	https://doi.org/10.1149/06801.3187ecst
Publication status	Published - 2015
Event	14th International Symposium on Solid Oxide Fuel Cells, SOFC 2015; held as part of the Electrochemical Society, ECS Conference on Electrochemical Energy Conversion and Storage - Glasgow, United Kingdom Duration: 2015 Jul 26 → 2015 Jul 31

Publication series

Name	ECS Transactions
Number	1
Volume	68
ISSN (Print)	1938-5862
ISSN (Electronic)	1938-6737

Conference

Conference	14th International Symposium on Solid Oxide Fuel Cells, SOFC 2015; held as part of the Electrochemical Society, ECS Conference on Electrochemical Energy Conversion and Storage
Country/Territory	United Kingdom
City	Glasgow
Period	15/7/26 → 15/7/31

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title = "Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell",

abstract = "Sintering of Ni particles in the Ni/Y-doped ZrO2 anode is a major obstacle to the widespread use of solid oxide fuel cell. In this study, we investigated the dopant effect on the diffusion of a Ni atom on the ZrO2 surface with dopants (Y and Al) by density functional theory calculations in order to inhibit the sintering. The most stable adsorption sites of the Ni atom on the Al-doped and Y-doped ZrO2 surfaces are the vicinity of the twofold-coordination oxygen atom and the vicinity of an oxygen vacancy, respectively. It is found that the most stable adsorption energy on the Al-doped ZrO2 surface is larger than that on the Y-doped ZrO2 surface. The analysis of diffusion path based on the potential energy surfaces of the Ni atom on the two surfaces shows that the energy barrier for the diffusion of the Ni atom on the Al-doped ZrO2 surface is larger than that on the Y-doped ZrO2 surface. The diffusion of the Ni atom on the Al-doped ZrO2 surface is more difficult than that on the Y-doped ZrO2 surface. This is because the Ni atom strongly bound to the twofold-coordination oxygen atom and the Ni atom is constrained in the Al-doped ZrO2 surface. Thus, the Ni sintering on the Al-doped ZrO2 surface is inhibited compared to that on the Y-doped ZrO2 surface.",

author = "Jingxiang Xu and Yuji Higuchi and Nobuki Ozawa and Momoji Kubo",

note = "Publisher Copyright: {\textcopyright} The Electrochemical Society.; 14th International Symposium on Solid Oxide Fuel Cells, SOFC 2015; held as part of the Electrochemical Society, ECS Conference on Electrochemical Energy Conversion and Storage ; Conference date: 26-07-2015 Through 31-07-2015",

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language = "English",

series = "ECS Transactions",

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Xu, J, Higuchi, Y, Ozawa, N & Kubo, M 2015, Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell. in K Eguchi & SC Singhal (eds), Solid Oxide Fuel Cells 14, SOFC 2015. 1 edn, ECS Transactions, no. 1, vol. 68, Electrochemical Society Inc., pp. 3187-3193, 14th International Symposium on Solid Oxide Fuel Cells, SOFC 2015; held as part of the Electrochemical Society, ECS Conference on Electrochemical Energy Conversion and Storage, Glasgow, United Kingdom, 15/7/26. https://doi.org/10.1149/06801.3187ecst

Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell. / Xu, Jingxiang; Higuchi, Yuji; Ozawa, Nobuki et al.
Solid Oxide Fuel Cells 14, SOFC 2015. ed. / K. Eguchi; S. C. Singhal. 1. ed. Electrochemical Society Inc., 2015. p. 3187-3193 (ECS Transactions; Vol. 68, No. 1).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell

AU - Xu, Jingxiang

AU - Higuchi, Yuji

AU - Ozawa, Nobuki

AU - Kubo, Momoji

N1 - Publisher Copyright: © The Electrochemical Society.

PY - 2015

Y1 - 2015

N2 - Sintering of Ni particles in the Ni/Y-doped ZrO2 anode is a major obstacle to the widespread use of solid oxide fuel cell. In this study, we investigated the dopant effect on the diffusion of a Ni atom on the ZrO2 surface with dopants (Y and Al) by density functional theory calculations in order to inhibit the sintering. The most stable adsorption sites of the Ni atom on the Al-doped and Y-doped ZrO2 surfaces are the vicinity of the twofold-coordination oxygen atom and the vicinity of an oxygen vacancy, respectively. It is found that the most stable adsorption energy on the Al-doped ZrO2 surface is larger than that on the Y-doped ZrO2 surface. The analysis of diffusion path based on the potential energy surfaces of the Ni atom on the two surfaces shows that the energy barrier for the diffusion of the Ni atom on the Al-doped ZrO2 surface is larger than that on the Y-doped ZrO2 surface. The diffusion of the Ni atom on the Al-doped ZrO2 surface is more difficult than that on the Y-doped ZrO2 surface. This is because the Ni atom strongly bound to the twofold-coordination oxygen atom and the Ni atom is constrained in the Al-doped ZrO2 surface. Thus, the Ni sintering on the Al-doped ZrO2 surface is inhibited compared to that on the Y-doped ZrO2 surface.

AB - Sintering of Ni particles in the Ni/Y-doped ZrO2 anode is a major obstacle to the widespread use of solid oxide fuel cell. In this study, we investigated the dopant effect on the diffusion of a Ni atom on the ZrO2 surface with dopants (Y and Al) by density functional theory calculations in order to inhibit the sintering. The most stable adsorption sites of the Ni atom on the Al-doped and Y-doped ZrO2 surfaces are the vicinity of the twofold-coordination oxygen atom and the vicinity of an oxygen vacancy, respectively. It is found that the most stable adsorption energy on the Al-doped ZrO2 surface is larger than that on the Y-doped ZrO2 surface. The analysis of diffusion path based on the potential energy surfaces of the Ni atom on the two surfaces shows that the energy barrier for the diffusion of the Ni atom on the Al-doped ZrO2 surface is larger than that on the Y-doped ZrO2 surface. The diffusion of the Ni atom on the Al-doped ZrO2 surface is more difficult than that on the Y-doped ZrO2 surface. This is because the Ni atom strongly bound to the twofold-coordination oxygen atom and the Ni atom is constrained in the Al-doped ZrO2 surface. Thus, the Ni sintering on the Al-doped ZrO2 surface is inhibited compared to that on the Y-doped ZrO2 surface.

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M3 - Conference contribution

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EP - 3193

BT - Solid Oxide Fuel Cells 14, SOFC 2015

A2 - Eguchi, K.

A2 - Singhal, S. C.

PB - Electrochemical Society Inc.

T2 - 14th International Symposium on Solid Oxide Fuel Cells, SOFC 2015; held as part of the Electrochemical Society, ECS Conference on Electrochemical Energy Conversion and Storage

Y2 - 26 July 2015 through 31 July 2015

ER -

Density functional theory study of dopant effect on sintering in the anode of solid oxide fuel cell

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