Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating

This study presents a new mathematical modeling study for interconnect oxidation analysis. A protective coating Mn1.5Co1.5O4 with different thicknessessare applied on ferritic stainless steel interconnect to address the chromium poisoning issue. Different Mn1.5Co1.5O4 coating thicknesses are applied...

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Published in:MATERIALS LETTERS
Main Authors: Huai, Tan Kang; Lowrance, Yohannes; Abd Rahman, Nurul Farhana; Yusop, Umira Asyikin; Abd Rahman, Hamimah; Jaidi, Zolhafizi; Tukimon, Mohd Faizal; Azami, Mohammad Saifulddin Mohd
Format: Article; Early Access
Language:English
Published: ELSEVIER 2024
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001151677400001
author Huai
Tan Kang; Lowrance
Yohannes; Abd Rahman
Nurul Farhana; Yusop
Umira Asyikin; Abd Rahman
Hamimah; Jaidi
Zolhafizi; Tukimon
Mohd Faizal; Azami
Mohammad Saifulddin Mohd
spellingShingle Huai
Tan Kang; Lowrance
Yohannes; Abd Rahman
Nurul Farhana; Yusop
Umira Asyikin; Abd Rahman
Hamimah; Jaidi
Zolhafizi; Tukimon
Mohd Faizal; Azami
Mohammad Saifulddin Mohd
Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
Materials Science; Physics
author_facet Huai
Tan Kang; Lowrance
Yohannes; Abd Rahman
Nurul Farhana; Yusop
Umira Asyikin; Abd Rahman
Hamimah; Jaidi
Zolhafizi; Tukimon
Mohd Faizal; Azami
Mohammad Saifulddin Mohd
author_sort Huai
spelling Huai, Tan Kang; Lowrance, Yohannes; Abd Rahman, Nurul Farhana; Yusop, Umira Asyikin; Abd Rahman, Hamimah; Jaidi, Zolhafizi; Tukimon, Mohd Faizal; Azami, Mohammad Saifulddin Mohd
Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
MATERIALS LETTERS
English
Article; Early Access
This study presents a new mathematical modeling study for interconnect oxidation analysis. A protective coating Mn1.5Co1.5O4 with different thicknessessare applied on ferritic stainless steel interconnect to address the chromium poisoning issue. Different Mn1.5Co1.5O4 coating thicknesses are applied. The coatings are assessed by surface morphology and phase structure. Developing coatings with various thicknesses is successful while maintaining consistent crystalline phases and coating morphology. The average coating thickness achieved at 35v for deposition times of 20, 30, and 40 s are 53.38 mu m, 68.13 mu m, and 85.13 mu m, respectively. The coating thickness, 68.13 mu m yields the lowest area specific resistance of 0.0469 ohm cm2 after 400 h of oxidation at 800 degrees C, compared to 0.0532 ohm cm2 and 0.0477 ohm cm2 for 53.38 mu m and 85.13 mu m The weight gains of the coated samples are recorded mathematically.This modeling approach results in a low weight gain and low oxidation kinetic rate of 0.139 mg cm-2 and 21.55 x 10-15 g2 cm-4 s-1, respectively for 68.13 mu m coating thickness It predicts an areaspecific resistance of 0.0451 ohm cm2 for the 35v 30 s coating, which is close to 0.0469 ohm cm2 experimental data.
ELSEVIER
0167-577X
1873-4979
2024
358

10.1016/j.matlet.2023.135825
Materials Science; Physics

WOS:001151677400001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001151677400001
title Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
title_short Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
title_full Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
title_fullStr Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
title_full_unstemmed Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
title_sort Mathematical modeling and experiment verification for the Solid oxide Fuel Cell Mn1.5Co1.5O4 interconnect coating
container_title MATERIALS LETTERS
language English
format Article; Early Access
description This study presents a new mathematical modeling study for interconnect oxidation analysis. A protective coating Mn1.5Co1.5O4 with different thicknessessare applied on ferritic stainless steel interconnect to address the chromium poisoning issue. Different Mn1.5Co1.5O4 coating thicknesses are applied. The coatings are assessed by surface morphology and phase structure. Developing coatings with various thicknesses is successful while maintaining consistent crystalline phases and coating morphology. The average coating thickness achieved at 35v for deposition times of 20, 30, and 40 s are 53.38 mu m, 68.13 mu m, and 85.13 mu m, respectively. The coating thickness, 68.13 mu m yields the lowest area specific resistance of 0.0469 ohm cm2 after 400 h of oxidation at 800 degrees C, compared to 0.0532 ohm cm2 and 0.0477 ohm cm2 for 53.38 mu m and 85.13 mu m The weight gains of the coated samples are recorded mathematically.This modeling approach results in a low weight gain and low oxidation kinetic rate of 0.139 mg cm-2 and 21.55 x 10-15 g2 cm-4 s-1, respectively for 68.13 mu m coating thickness It predicts an areaspecific resistance of 0.0451 ohm cm2 for the 35v 30 s coating, which is close to 0.0469 ohm cm2 experimental data.
publisher ELSEVIER
issn 0167-577X
1873-4979
publishDate 2024
container_volume 358
container_issue
doi_str_mv 10.1016/j.matlet.2023.135825
topic Materials Science; Physics
topic_facet Materials Science; Physics
accesstype
id WOS:001151677400001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001151677400001
record_format wos
collection Web of Science (WoS)
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