Demonstrating the potential of iron-doped strontium titanate electrolyte with high-performance for low temperature ceramic fuel cells

M. A.K.Yousaf Shah; Yuzheng Lu; Naveed Mushtaq; Sajid Rauf; Muhammad Yousaf; Muhammad Imran Asghar; Peter D. Lund; Bin Zhu

doi:10.1016/j.renene.2022.06.154

Demonstrating the potential of iron-doped strontium titanate electrolyte with high-performance for low temperature ceramic fuel cells

M. A.K.Yousaf Shah, Yuzheng Lu, Naveed Mushtaq, Sajid Rauf, Muhammad Yousaf, Muhammad Imran Asghar^*, Peter D. Lund, Bin Zhu

^*Corresponding author for this work

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Abstract

Electrolytes with high-proton conduction and low activation energy are attractive for reducing the high operating temperature of solid-oxide fuel cells to less than <600 °C. In this work, we have fabricated semiconducting electrolyte SrFeTiO_3-δ (SFT) material exhibiting high ionic conduction and exceptionally high protonic conduction at low operating temperature but with low electronic conduction to evade the short-circuiting issue. The prepared fuel cell device exhibited high open-circuit voltage (OCV) and a high-power output of 534 mW/cm², of which 474 mW/cm² could be for sure be related to the protonic part. The current study suggests that usage of semiconductor SrFeTiO_3-δ facilitates a high concentration of oxygen vacancies on the surface of SFT, which mainly benefits proton conduction. Moreover, lower grain boundary resistance leads to obtain higher performance. Also, the Schottky junction phenomena are proposed to inhibit the e-conduction and excel the ions transportation. The high performance and ionic conductivity suggest that SFT could be a promising electrolyte for protonic ceramic fuel cells.

Original language	English
Pages (from-to)	901-911
Number of pages	11
Journal	Renewable Energy
Volume	196
DOIs	https://doi.org/10.1016/j.renene.2022.06.154
Publication status	Published - Aug 2022
MoE publication type	A1 Journal article-refereed

Keywords

Ceramic fuel cell (CFC)
Electrolyte
Higher fuel cell performance
Proton conducting
Schottky junction

UN SDGs

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

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Demonstrating the potential of iron-doped strontium titanate electrolyte with high-performance for low temperature ceramic fuel cellsFinal published version, 4.02 MBLicence: CC BY

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title = "Demonstrating the potential of iron-doped strontium titanate electrolyte with high-performance for low temperature ceramic fuel cells",

abstract = "Electrolytes with high-proton conduction and low activation energy are attractive for reducing the high operating temperature of solid-oxide fuel cells to less than <600 °C. In this work, we have fabricated semiconducting electrolyte SrFeTiO3-δ (SFT) material exhibiting high ionic conduction and exceptionally high protonic conduction at low operating temperature but with low electronic conduction to evade the short-circuiting issue. The prepared fuel cell device exhibited high open-circuit voltage (OCV) and a high-power output of 534 mW/cm2, of which 474 mW/cm2 could be for sure be related to the protonic part. The current study suggests that usage of semiconductor SrFeTiO3-δ facilitates a high concentration of oxygen vacancies on the surface of SFT, which mainly benefits proton conduction. Moreover, lower grain boundary resistance leads to obtain higher performance. Also, the Schottky junction phenomena are proposed to inhibit the e-conduction and excel the ions transportation. The high performance and ionic conductivity suggest that SFT could be a promising electrolyte for protonic ceramic fuel cells.",

keywords = "Ceramic fuel cell (CFC), Electrolyte, Higher fuel cell performance, Proton conducting, Schottky junction",

author = "Shah, {M. A.K.Yousaf} and Yuzheng Lu and Naveed Mushtaq and Sajid Rauf and Muhammad Yousaf and Asghar, {Muhammad Imran} and Lund, {Peter D.} and Bin Zhu",

note = "Funding Information: This work was supported Southeast University (SEU) project 3203002003A1 and National Natural Science Foundation of China (NSFC) under the grant 51772080 and 11604088 . Jiangsu Provincial Innovation and Entrepreneurship Talent program Project No. JSSCRC2021491 . Industry-University-Research Cooperation Project of Jiangsu Province in China , Grant No. BY2021057 . Dr. Asghar thanks the Hubei Talent 100 program and Academy of Finland ( 13329016 , 13322738 ) for their financial support. Publisher Copyright: {\textcopyright} 2022 The Authors",

year = "2022",

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doi = "10.1016/j.renene.2022.06.154",

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AU - Shah, M. A.K.Yousaf

AU - Lu, Yuzheng

AU - Mushtaq, Naveed

AU - Rauf, Sajid

AU - Yousaf, Muhammad

AU - Asghar, Muhammad Imran

AU - Lund, Peter D.

AU - Zhu, Bin

N1 - Funding Information: This work was supported Southeast University (SEU) project 3203002003A1 and National Natural Science Foundation of China (NSFC) under the grant 51772080 and 11604088 . Jiangsu Provincial Innovation and Entrepreneurship Talent program Project No. JSSCRC2021491 . Industry-University-Research Cooperation Project of Jiangsu Province in China , Grant No. BY2021057 . Dr. Asghar thanks the Hubei Talent 100 program and Academy of Finland ( 13329016 , 13322738 ) for their financial support. Publisher Copyright: © 2022 The Authors

PY - 2022/8

Y1 - 2022/8

N2 - Electrolytes with high-proton conduction and low activation energy are attractive for reducing the high operating temperature of solid-oxide fuel cells to less than <600 °C. In this work, we have fabricated semiconducting electrolyte SrFeTiO3-δ (SFT) material exhibiting high ionic conduction and exceptionally high protonic conduction at low operating temperature but with low electronic conduction to evade the short-circuiting issue. The prepared fuel cell device exhibited high open-circuit voltage (OCV) and a high-power output of 534 mW/cm2, of which 474 mW/cm2 could be for sure be related to the protonic part. The current study suggests that usage of semiconductor SrFeTiO3-δ facilitates a high concentration of oxygen vacancies on the surface of SFT, which mainly benefits proton conduction. Moreover, lower grain boundary resistance leads to obtain higher performance. Also, the Schottky junction phenomena are proposed to inhibit the e-conduction and excel the ions transportation. The high performance and ionic conductivity suggest that SFT could be a promising electrolyte for protonic ceramic fuel cells.

AB - Electrolytes with high-proton conduction and low activation energy are attractive for reducing the high operating temperature of solid-oxide fuel cells to less than <600 °C. In this work, we have fabricated semiconducting electrolyte SrFeTiO3-δ (SFT) material exhibiting high ionic conduction and exceptionally high protonic conduction at low operating temperature but with low electronic conduction to evade the short-circuiting issue. The prepared fuel cell device exhibited high open-circuit voltage (OCV) and a high-power output of 534 mW/cm2, of which 474 mW/cm2 could be for sure be related to the protonic part. The current study suggests that usage of semiconductor SrFeTiO3-δ facilitates a high concentration of oxygen vacancies on the surface of SFT, which mainly benefits proton conduction. Moreover, lower grain boundary resistance leads to obtain higher performance. Also, the Schottky junction phenomena are proposed to inhibit the e-conduction and excel the ions transportation. The high performance and ionic conductivity suggest that SFT could be a promising electrolyte for protonic ceramic fuel cells.

KW - Ceramic fuel cell (CFC)

KW - Electrolyte

KW - Higher fuel cell performance

KW - Proton conducting

KW - Schottky junction

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DO - 10.1016/j.renene.2022.06.154

M3 - Article

AN - SCOPUS:85134728745

VL - 196

SP - 901

EP - 911

JO - Renewable Energy

JF - Renewable Energy

SN - 0960-1481

ER -

Demonstrating the potential of iron-doped strontium titanate electrolyte with high-performance for low temperature ceramic fuel cells

Abstract

Keywords

UN SDGs

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Leading-edge next generation fuel cell devices

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Demonstrating the potential of iron-doped strontium titanate electrolyte with high-performance for low temperature ceramic fuel cells

Abstract

Keywords

UN SDGs

Access to Document

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Fingerprint

Projects

Leading-edge next generation fuel cell devices

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