A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase
Prolonged annealing of La0.6Sr0.4Co0.2Fe0.8O3-� (LSCF) at 700 �C for 1000 h resulted in phase segregation on the surface in the form of submicron-sized SrO on the grains and micron-sized CoFe2O4 particles near the grain boundaries during electrical conductivity relaxation (ECR) measurements. The pre...
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my.uniten.dspace-368092025-03-03T15:44:50Z A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase Saher S. Tan C.Y. Ramesh S. Yap B.K. Ong B.H. Mo K.H. Al-Furjan M.S.H. 36134688200 16029485400 41061958200 26649255900 7102342460 55915884700 57888381600 Cathodes Coatings Electrolytic reduction Grain boundaries Iron compounds Lanthanum compounds Manganese compounds Nickel compounds Nozzles Segregation (metallography) Solid oxide fuel cells (SOFC) Strontium compounds Surface segregation Temperature Ultrasonic effects Fuel cell cathodes In-phase Mixed conducting oxides Oxygen exchange kinetics Phase segregations Prolonged annealing Solid oxide fuel cell cathode Solid-oxide fuel cell Submicron-sized Surface coverages Oxygen Prolonged annealing of La0.6Sr0.4Co0.2Fe0.8O3-� (LSCF) at 700 �C for 1000 h resulted in phase segregation on the surface in the form of submicron-sized SrO on the grains and micron-sized CoFe2O4 particles near the grain boundaries during electrical conductivity relaxation (ECR) measurements. The presence of segregated particles results in a substantial decrease in the surface exchange coefficient, kchem. To mitigate this issue, the LSCF electrodes underwent a systematic coating process with the K2NiF4-structure Pr4Ni3O10+� (PNO), while varying the loading content, thickness, and porosity. This is achieved by adjusting the gap between the nozzle exit and LSCF surface, ranging from 2 cm to 9 cm, coupled with the application of ultrasonic vibration of the nozzle chamber operating between 40 kHz and 180 kHz. Optimal surface coverage with a loading content of 0.28 mg cm?2 referred to as PNO5 results in a significant increase in kchem by up to one and a half order of magnitude compared to bare LSCF. The PNO coating effectively suppresses phase segregation during prolonged exposure, resulting in a substantial decrease in degradation. The improved performance is attributed to the optimal surface coverage of coated particulates, which enhances the active sites for oxygen reduction reaction (ORR) and the triple phase boundary (TPB) area. These exceptional characteristics position PNO coated LSCF as a highly promising cathode option for low temperature solid oxide fuel cells (SOFCs). ? 2023 Elsevier B.V. Final 2025-03-03T07:44:50Z 2025-03-03T07:44:50Z 2024 Article 10.1016/j.jpowsour.2023.233899 2-s2.0-85179609967 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85179609967&doi=10.1016%2fj.jpowsour.2023.233899&partnerID=40&md5=426f3778297716efcd94d634f2d9f5e4 https://irepository.uniten.edu.my/handle/123456789/36809 592 233899 Elsevier B.V. Scopus |
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Cathodes Coatings Electrolytic reduction Grain boundaries Iron compounds Lanthanum compounds Manganese compounds Nickel compounds Nozzles Segregation (metallography) Solid oxide fuel cells (SOFC) Strontium compounds Surface segregation Temperature Ultrasonic effects Fuel cell cathodes In-phase Mixed conducting oxides Oxygen exchange kinetics Phase segregations Prolonged annealing Solid oxide fuel cell cathode Solid-oxide fuel cell Submicron-sized Surface coverages Oxygen |
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Cathodes Coatings Electrolytic reduction Grain boundaries Iron compounds Lanthanum compounds Manganese compounds Nickel compounds Nozzles Segregation (metallography) Solid oxide fuel cells (SOFC) Strontium compounds Surface segregation Temperature Ultrasonic effects Fuel cell cathodes In-phase Mixed conducting oxides Oxygen exchange kinetics Phase segregations Prolonged annealing Solid oxide fuel cell cathode Solid-oxide fuel cell Submicron-sized Surface coverages Oxygen Saher S. Tan C.Y. Ramesh S. Yap B.K. Ong B.H. Mo K.H. Al-Furjan M.S.H. A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase |
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Prolonged annealing of La0.6Sr0.4Co0.2Fe0.8O3-� (LSCF) at 700 �C for 1000 h resulted in phase segregation on the surface in the form of submicron-sized SrO on the grains and micron-sized CoFe2O4 particles near the grain boundaries during electrical conductivity relaxation (ECR) measurements. The presence of segregated particles results in a substantial decrease in the surface exchange coefficient, kchem. To mitigate this issue, the LSCF electrodes underwent a systematic coating process with the K2NiF4-structure Pr4Ni3O10+� (PNO), while varying the loading content, thickness, and porosity. This is achieved by adjusting the gap between the nozzle exit and LSCF surface, ranging from 2 cm to 9 cm, coupled with the application of ultrasonic vibration of the nozzle chamber operating between 40 kHz and 180 kHz. Optimal surface coverage with a loading content of 0.28 mg cm?2 referred to as PNO5 results in a significant increase in kchem by up to one and a half order of magnitude compared to bare LSCF. The PNO coating effectively suppresses phase segregation during prolonged exposure, resulting in a substantial decrease in degradation. The improved performance is attributed to the optimal surface coverage of coated particulates, which enhances the active sites for oxygen reduction reaction (ORR) and the triple phase boundary (TPB) area. These exceptional characteristics position PNO coated LSCF as a highly promising cathode option for low temperature solid oxide fuel cells (SOFCs). ? 2023 Elsevier B.V. |
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36134688200 |
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36134688200 Saher S. Tan C.Y. Ramesh S. Yap B.K. Ong B.H. Mo K.H. Al-Furjan M.S.H. |
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Article |
| author |
Saher S. Tan C.Y. Ramesh S. Yap B.K. Ong B.H. Mo K.H. Al-Furjan M.S.H. |
| author_sort |
Saher S. |
| title |
A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase |
| title_short |
A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase |
| title_full |
A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase |
| title_fullStr |
A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase |
| title_full_unstemmed |
A way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with K2NiF4-Structure Pr4Ni3O10+� phase |
| title_sort |
way to limit the long-term degradation of solid oxide fuel cell cathode by decorating the surface with k2nif4-structure pr4ni3o10+� phase |
| publisher |
Elsevier B.V. |
| publishDate |
2025 |
| _version_ |
1825816147343179776 |
| score |
13.244413 |