Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder

To obtain dense, high-quality electrolytes, sintering of the proton-conducting electrolyte BaCe0.6Zr0.2Y0.2O3 (BCZY) in protonic ceramic fuel cells (PCFCs) should be conducted at relatively high temperatures. However, in the co-sintering of a porous anode substrate and electrolyte thin film, high si...

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Published in:CERAMICS INTERNATIONAL
Main Authors: Cheng, Po-Chun; Lee, Kan-Rong; Bhavanari, Mallikarjun; Su, Pei-Chen; Osman, Nafisah; Lee, Sheng-Wei; Tseng, Chung-Jen
Format: Article
Language:English
Published: ELSEVIER SCI LTD 2023
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001150034400001
author Cheng
Po-Chun; Lee
Kan-Rong; Bhavanari
Mallikarjun; Su
Pei-Chen; Osman
Nafisah; Lee
Sheng-Wei; Tseng
Chung-Jen
spellingShingle Cheng
Po-Chun; Lee
Kan-Rong; Bhavanari
Mallikarjun; Su
Pei-Chen; Osman
Nafisah; Lee
Sheng-Wei; Tseng
Chung-Jen
Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
Materials Science
author_facet Cheng
Po-Chun; Lee
Kan-Rong; Bhavanari
Mallikarjun; Su
Pei-Chen; Osman
Nafisah; Lee
Sheng-Wei; Tseng
Chung-Jen
author_sort Cheng
spelling Cheng, Po-Chun; Lee, Kan-Rong; Bhavanari, Mallikarjun; Su, Pei-Chen; Osman, Nafisah; Lee, Sheng-Wei; Tseng, Chung-Jen
Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
CERAMICS INTERNATIONAL
English
Article
To obtain dense, high-quality electrolytes, sintering of the proton-conducting electrolyte BaCe0.6Zr0.2Y0.2O3 (BCZY) in protonic ceramic fuel cells (PCFCs) should be conducted at relatively high temperatures. However, in the co-sintering of a porous anode substrate and electrolyte thin film, high sintering temperatures often cause the coarsening of the NiO-BCZY anode, thus reducing the number of electrocatalytic active sites for H2 oxidation as well as degrading cell performance. A scalable nanomilling process is proposed to reduce electrolyte sintering temperature to maintain triple phase boundary, good electron and proton transport in PCFC anode. By using the nanomilling process, BCZY nanoparticles more than halved the original diameter (from 297 nm to 131 nm) were produced. The co-sintering temperature can be lowered. The cell sintered at 1400 degrees C exhibited the highest peak power density of 490 mW/cm2, 38% higher than that of un-nanomilled process. The substantial improvement in cell performance can be attributed to the lower co-sintering temperature, which caused less coarsening of the NiO anode. This preserved a greater number of electrocatalytic active sites for H2 oxidation by Ni in cell operation, as evidenced by the 50% decrease in charge transfer resistance from electrochemical impedance measurements.
ELSEVIER SCI LTD
0272-8842
1873-3956
2023
49
19
10.1016/j.ceramint.2023.07.188
Materials Science

WOS:001150034400001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001150034400001
title Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
title_short Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
title_full Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
title_fullStr Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
title_full_unstemmed Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
title_sort Enhancing protonic ceramic fuel cell performance through nanomilling of BCZY electrolyte powder
container_title CERAMICS INTERNATIONAL
language English
format Article
description To obtain dense, high-quality electrolytes, sintering of the proton-conducting electrolyte BaCe0.6Zr0.2Y0.2O3 (BCZY) in protonic ceramic fuel cells (PCFCs) should be conducted at relatively high temperatures. However, in the co-sintering of a porous anode substrate and electrolyte thin film, high sintering temperatures often cause the coarsening of the NiO-BCZY anode, thus reducing the number of electrocatalytic active sites for H2 oxidation as well as degrading cell performance. A scalable nanomilling process is proposed to reduce electrolyte sintering temperature to maintain triple phase boundary, good electron and proton transport in PCFC anode. By using the nanomilling process, BCZY nanoparticles more than halved the original diameter (from 297 nm to 131 nm) were produced. The co-sintering temperature can be lowered. The cell sintered at 1400 degrees C exhibited the highest peak power density of 490 mW/cm2, 38% higher than that of un-nanomilled process. The substantial improvement in cell performance can be attributed to the lower co-sintering temperature, which caused less coarsening of the NiO anode. This preserved a greater number of electrocatalytic active sites for H2 oxidation by Ni in cell operation, as evidenced by the 50% decrease in charge transfer resistance from electrochemical impedance measurements.
publisher ELSEVIER SCI LTD
issn 0272-8842
1873-3956
publishDate 2023
container_volume 49
container_issue 19
doi_str_mv 10.1016/j.ceramint.2023.07.188
topic Materials Science
topic_facet Materials Science
accesstype
id WOS:001150034400001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001150034400001
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collection Web of Science (WoS)
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