Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms

H. Yokokawa; M. Suzuki; M. Yoda; T. Suto; K. Tomida; K. Hiwatashi; M. Shimazu; A. Kawakami; H. Sumi; M. Ohmori; T. Ryu; N. Mori; M. Iha; S. Yatsuzuka; K. Yamaji; H. Kishimoto; K. Develos-Bagarinao; T. Shimonosono; K. Sasaki; S. Taniguchi; T. Kawada; M. Muramatsu; K. Terada; K. Eguchi; T. Matsui; H. Iwai; M. Kishimoto; N. Shikazono; Y. Mugikura; T. Yamamoto; M. Yoshikawa; K. Yasumoto; K. Asano; Y. Matsuzaki; K. Sato; T. Somekawa

doi:10.1002/fuce.201800187

Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms

H. Yokokawa, M. Suzuki, M. Yoda, T. Suto, K. Tomida, K. Hiwatashi, M. Shimazu, A. Kawakami, H. Sumi, M. Ohmori, T. Ryu, N. Mori, M. Iha, S. Yatsuzuka, K. Yamaji, H. Kishimoto, K. Develos-Bagarinao, T. Shimonosono, K. Sasaki, S. TaniguchiT. Kawada, M. Muramatsu, K. Terada, K. Eguchi, T. Matsui, H. Iwai, M. Kishimoto, N. Shikazono, Y. Mugikura, T. Yamamoto, M. Yoshikawa, K. Yasumoto, K. Asano, Y. Matsuzaki, K. Sato, T. Somekawa

ENV - Environmental Studies for Advanced Society

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

15 Citations (Scopus)

Abstract

Achievements of NEDO durability projects on SOFC mode are summarized with a focus on the physicochemical mechanisms characterized by diffusion properties of cell components and chemical reactions of cell components with gaseous impurities. Ni sintering and depletion including impurity (P, B, S) effects have been examined in terms of the surface/interface energies of Ni/oxide cermet anodes. The conductivity degradation due to the transformation of the cubic YSZ electrolyte was found to be characterized in terms of two time constants for the reductive and the oxidative regions to be determined by the Y-diffusivity and its enhancement on NiO internal reduction in YSZ, while observed gaps in conductivity degradation behavior between stacks and button cells were ascribed to differences in those physicochemical properties involved, namely cation diffusion and kinetics associated with NiO internal reduction. The cathode performance degradation due to sulfur poisoning exhibits a variety of dependences on the microstructure (dense or porous) of doped-ceria interlayers, the thickness of YSZ electrolyte and the humidity in the anode atmosphere, suggesting effects of protons in the cathode vicinity and the SrO activity changes during fabrication the LSCF/GDC/YSZ multilayers. Some defect chemical considerations were made on how such defects are affected by fabrication processes.

Original language	English
Pages (from-to)	311-339
Number of pages	29
Journal	Fuel Cells
Volume	19
Issue number	4
DOIs	https://doi.org/10.1002/fuce.201800187
Publication status	Published - 2019

Keywords

Anode Degradation, Cathode Degradation, Chromium
Conductivity Degradation
Diffusion
Durability
Impurities
Simulation
Solid Oxide Fuel Cell
Sulfur

ASJC Scopus subject areas

Renewable Energy, Sustainability and the Environment
Energy Engineering and Power Technology

UN SDGs

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

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10.1002/fuce.201800187

Cite this

Yokokawa, H., Suzuki, M., Yoda, M., Suto, T., Tomida, K., Hiwatashi, K., Shimazu, M., Kawakami, A., Sumi, H., Ohmori, M., Ryu, T., Mori, N., Iha, M., Yatsuzuka, S., Yamaji, K., Kishimoto, H., Develos-Bagarinao, K., Shimonosono, T., Sasaki, K., ... Somekawa, T. (2019). Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms. Fuel Cells, 19(4), 311-339. https://doi.org/10.1002/fuce.201800187

Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms. / Yokokawa, H.; Suzuki, M.; Yoda, M.; Suto, T.; Tomida, K.; Hiwatashi, K.; Shimazu, M.; Kawakami, A.; Sumi, H.; Ohmori, M.; Ryu, T.; Mori, N.; Iha, M.; Yatsuzuka, S.; Yamaji, K.; Kishimoto, H.; Develos-Bagarinao, K.; Shimonosono, T.; Sasaki, K.; Taniguchi, S.; Kawada, T.; Muramatsu, M.; Terada, K.; Eguchi, K.; Matsui, T.; Iwai, H.; Kishimoto, M.; Shikazono, N.; Mugikura, Y.; Yamamoto, T.; Yoshikawa, M.; Yasumoto, K.; Asano, K.; Matsuzaki, Y.; Sato, K.; Somekawa, T.

In: Fuel Cells, Vol. 19, No. 4, 2019, p. 311-339.

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

Yokokawa, H, Suzuki, M, Yoda, M, Suto, T, Tomida, K, Hiwatashi, K, Shimazu, M, Kawakami, A, Sumi, H, Ohmori, M, Ryu, T, Mori, N, Iha, M, Yatsuzuka, S, Yamaji, K, Kishimoto, H, Develos-Bagarinao, K, Shimonosono, T, Sasaki, K, Taniguchi, S, Kawada, T, Muramatsu, M, Terada, K, Eguchi, K, Matsui, T, Iwai, H, Kishimoto, M, Shikazono, N, Mugikura, Y, Yamamoto, T, Yoshikawa, M, Yasumoto, K, Asano, K, Matsuzaki, Y, Sato, K & Somekawa, T 2019, 'Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms', Fuel Cells, vol. 19, no. 4, pp. 311-339. https://doi.org/10.1002/fuce.201800187

Yokokawa, H. ; Suzuki, M. ; Yoda, M. ; Suto, T. ; Tomida, K. ; Hiwatashi, K. ; Shimazu, M. ; Kawakami, A. ; Sumi, H. ; Ohmori, M. ; Ryu, T. ; Mori, N. ; Iha, M. ; Yatsuzuka, S. ; Yamaji, K. ; Kishimoto, H. ; Develos-Bagarinao, K. ; Shimonosono, T. ; Sasaki, K. ; Taniguchi, S. ; Kawada, T. ; Muramatsu, M. ; Terada, K. ; Eguchi, K. ; Matsui, T. ; Iwai, H. ; Kishimoto, M. ; Shikazono, N. ; Mugikura, Y. ; Yamamoto, T. ; Yoshikawa, M. ; Yasumoto, K. ; Asano, K. ; Matsuzaki, Y. ; Sato, K. ; Somekawa, T. / Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms. In: Fuel Cells. 2019 ; Vol. 19, No. 4. pp. 311-339.

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title = "Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms",

abstract = "Achievements of NEDO durability projects on SOFC mode are summarized with a focus on the physicochemical mechanisms characterized by diffusion properties of cell components and chemical reactions of cell components with gaseous impurities. Ni sintering and depletion including impurity (P, B, S) effects have been examined in terms of the surface/interface energies of Ni/oxide cermet anodes. The conductivity degradation due to the transformation of the cubic YSZ electrolyte was found to be characterized in terms of two time constants for the reductive and the oxidative regions to be determined by the Y-diffusivity and its enhancement on NiO internal reduction in YSZ, while observed gaps in conductivity degradation behavior between stacks and button cells were ascribed to differences in those physicochemical properties involved, namely cation diffusion and kinetics associated with NiO internal reduction. The cathode performance degradation due to sulfur poisoning exhibits a variety of dependences on the microstructure (dense or porous) of doped-ceria interlayers, the thickness of YSZ electrolyte and the humidity in the anode atmosphere, suggesting effects of protons in the cathode vicinity and the SrO activity changes during fabrication the LSCF/GDC/YSZ multilayers. Some defect chemical considerations were made on how such defects are affected by fabrication processes.",

keywords = "Anode Degradation, Cathode Degradation, Chromium, Conductivity Degradation, Diffusion, Durability, Impurities, Simulation, Solid Oxide Fuel Cell, Sulfur",

author = "H. Yokokawa and M. Suzuki and M. Yoda and T. Suto and K. Tomida and K. Hiwatashi and M. Shimazu and A. Kawakami and H. Sumi and M. Ohmori and T. Ryu and N. Mori and M. Iha and S. Yatsuzuka and K. Yamaji and H. Kishimoto and K. Develos-Bagarinao and T. Shimonosono and K. Sasaki and S. Taniguchi and T. Kawada and M. Muramatsu and K. Terada and K. Eguchi and T. Matsui and H. Iwai and M. Kishimoto and N. Shikazono and Y. Mugikura and T. Yamamoto and M. Yoshikawa and K. Yasumoto and K. Asano and Y. Matsuzaki and K. Sato and T. Somekawa",

note = "Funding Information: This work was made under the contract with NEDO on Fundamental study for rapid evaluation method of SOFC durability in ?Technology development for promoting SOFC Commercialization.? This investigation has been conducted with cooperation with Kyocera: One of us (HY) as project leader would like to thank Yuichi Hori, Takashi Shigehisa and other members for their help in experimentation in CRIEPI, for discussions on technological aspects of Kyocera stacks and for permission of use of figures concerning Kyocera stacks. HY would like to thank also Sebastian Dierickx (KIT, IAU-WET) for his help in improving the format of all figures in the manuscript. Publisher Copyright: {\textcopyright} 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim",

year = "2019",

doi = "10.1002/fuce.201800187",

language = "English",

volume = "19",

pages = "311--339",

journal = "Fuel Cells",

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AU - Yokokawa, H.

AU - Suzuki, M.

AU - Yoda, M.

AU - Suto, T.

AU - Tomida, K.

AU - Hiwatashi, K.

AU - Shimazu, M.

AU - Kawakami, A.

AU - Sumi, H.

AU - Ohmori, M.

AU - Ryu, T.

AU - Mori, N.

AU - Iha, M.

AU - Yatsuzuka, S.

AU - Yamaji, K.

AU - Kishimoto, H.

AU - Develos-Bagarinao, K.

AU - Shimonosono, T.

AU - Sasaki, K.

AU - Taniguchi, S.

AU - Kawada, T.

AU - Muramatsu, M.

AU - Terada, K.

AU - Eguchi, K.

AU - Matsui, T.

AU - Iwai, H.

AU - Kishimoto, M.

AU - Shikazono, N.

AU - Mugikura, Y.

AU - Yamamoto, T.

AU - Yoshikawa, M.

AU - Yasumoto, K.

AU - Asano, K.

AU - Matsuzaki, Y.

AU - Sato, K.

AU - Somekawa, T.

N1 - Funding Information: This work was made under the contract with NEDO on Fundamental study for rapid evaluation method of SOFC durability in ?Technology development for promoting SOFC Commercialization.? This investigation has been conducted with cooperation with Kyocera: One of us (HY) as project leader would like to thank Yuichi Hori, Takashi Shigehisa and other members for their help in experimentation in CRIEPI, for discussions on technological aspects of Kyocera stacks and for permission of use of figures concerning Kyocera stacks. HY would like to thank also Sebastian Dierickx (KIT, IAU-WET) for his help in improving the format of all figures in the manuscript. Publisher Copyright: © 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

PY - 2019

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N2 - Achievements of NEDO durability projects on SOFC mode are summarized with a focus on the physicochemical mechanisms characterized by diffusion properties of cell components and chemical reactions of cell components with gaseous impurities. Ni sintering and depletion including impurity (P, B, S) effects have been examined in terms of the surface/interface energies of Ni/oxide cermet anodes. The conductivity degradation due to the transformation of the cubic YSZ electrolyte was found to be characterized in terms of two time constants for the reductive and the oxidative regions to be determined by the Y-diffusivity and its enhancement on NiO internal reduction in YSZ, while observed gaps in conductivity degradation behavior between stacks and button cells were ascribed to differences in those physicochemical properties involved, namely cation diffusion and kinetics associated with NiO internal reduction. The cathode performance degradation due to sulfur poisoning exhibits a variety of dependences on the microstructure (dense or porous) of doped-ceria interlayers, the thickness of YSZ electrolyte and the humidity in the anode atmosphere, suggesting effects of protons in the cathode vicinity and the SrO activity changes during fabrication the LSCF/GDC/YSZ multilayers. Some defect chemical considerations were made on how such defects are affected by fabrication processes.

AB - Achievements of NEDO durability projects on SOFC mode are summarized with a focus on the physicochemical mechanisms characterized by diffusion properties of cell components and chemical reactions of cell components with gaseous impurities. Ni sintering and depletion including impurity (P, B, S) effects have been examined in terms of the surface/interface energies of Ni/oxide cermet anodes. The conductivity degradation due to the transformation of the cubic YSZ electrolyte was found to be characterized in terms of two time constants for the reductive and the oxidative regions to be determined by the Y-diffusivity and its enhancement on NiO internal reduction in YSZ, while observed gaps in conductivity degradation behavior between stacks and button cells were ascribed to differences in those physicochemical properties involved, namely cation diffusion and kinetics associated with NiO internal reduction. The cathode performance degradation due to sulfur poisoning exhibits a variety of dependences on the microstructure (dense or porous) of doped-ceria interlayers, the thickness of YSZ electrolyte and the humidity in the anode atmosphere, suggesting effects of protons in the cathode vicinity and the SrO activity changes during fabrication the LSCF/GDC/YSZ multilayers. Some defect chemical considerations were made on how such defects are affected by fabrication processes.

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KW - Conductivity Degradation

KW - Diffusion

KW - Durability

KW - Impurities

KW - Simulation

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KW - Sulfur

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Achievements of NEDO Durability Projects on SOFC Stacks in the Light of Physicochemical Mechanisms

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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