Standard

Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes. / Ain, Qurat ul; Irshad, Muneeb; Butt, Muhammad и др.
в: Frontiers in Chemistry, Том 11, 1322475, 2023.

Результаты исследований: Вклад в журналСтатьяРецензирование

Harvard

Ain, QU, Irshad, M, Butt, M, Tabish, A, Hanif, M, Khalid, M, Ghaffar, R, Rafique, M, Shawar Kazmi, S, Siraj, K, Hafez, A, Abd-Rabboh, H, Zmrhalova, Z, Filonova, E, Medvedev, D & Motola, M 2023, 'Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes', Frontiers in Chemistry, Том. 11, 1322475. https://doi.org/10.3389/fchem.2023.1322475

APA

Ain, Q. U., Irshad, M., Butt, M., Tabish, A., Hanif, M., Khalid, M., Ghaffar, R., Rafique, M., Shawar Kazmi, S., Siraj, K., Hafez, A., Abd-Rabboh, H., Zmrhalova, Z., Filonova, E., Medvedev, D., & Motola, M. (2023). Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes. Frontiers in Chemistry, 11, [1322475]. https://doi.org/10.3389/fchem.2023.1322475

Vancouver

Ain QU, Irshad M, Butt M, Tabish A, Hanif M, Khalid M и др. Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes. Frontiers in Chemistry. 2023;11:1322475. doi: 10.3389/fchem.2023.1322475

Author

Ain, Qurat ul ; Irshad, Muneeb ; Butt, Muhammad и др. / Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes. в: Frontiers in Chemistry. 2023 ; Том 11.

BibTeX

@article{e0d581808c9f4daf9ee950ae7c175022,
title = "Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes",
abstract = "In this study, BaZr0.87Y0.1M0.03O3−δ perovskite electrolytes with sintering aids (M = Mn, Co, and Fe) were synthesized by a sustainable approach using spinach powder as a chelating agent and then compared with chemically synthesized BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes for intermediate temperature SOFCs. This is the first example of such a sustainable synthesis of perovskite materials with sintering aids. Structural analysis revealed the presence of a cubic perovskite structure in BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) samples synthesized by both green and conventional chemical methods. No significant secondary phases were observed in the samples synthesized by a sustainable approach. The observed phenomena of plane shift were because of the disparities between ionic radii of the dopants, impurities, and host materials. The surface morphology analysis revealed a denser microstructure for the electrolytes synthesized via green routes due to metallic impurities in the organic chelating agent. The absence of significant impurities was also observed by compositional analysis, while functional groups were identified through Fourier-transform infrared spectroscopy. Conductivity measurements showed that BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes synthesized by oxalic acid have higher conductivities compared to BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes synthesized by the green approach. The button cells employing BaZr0.87Y0.1Co0.03O3−δ electrolytes synthesized by the chemical and green routes achieved peak power densities 344 and 271 mW·cm−2 respectively, suggesting that the novel green route can be applied to synthesize SOFC perovskite materials with minimal environmental impact and without significantly compromising cell performance. ",
author = "Ain, {Qurat ul} and Muneeb Irshad and Muhammad Butt and Asif Tabish and Muhammad Hanif and Muhammad Khalid and Rabia Ghaffar and Muhammad Rafique and {Shawar Kazmi}, Syeda and Khurram Siraj and Amal Hafez and Hisham Abd-Rabboh and Zuzana Zmrhalova and Elena Filonova and Dmitry Medvedev and Martin Motola",
note = "The authors declare financial support was received for the research, authorship, and/or publication of this article. The authors extend their appreciation to the Deanship of Scientific Research at King Khalid University for funding this work through the Large Groups Project under grant number (RGP.2/335/44).",
year = "2023",
doi = "10.3389/fchem.2023.1322475",
language = "English",
volume = "11",
journal = "Frontiers in Chemistry",
issn = "2296-2646",
publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Towards sustainable electrochemistry: green synthesis and sintering aid modulations in the development of BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) IT-SOFC electrolytes

AU - Ain, Qurat ul

AU - Irshad, Muneeb

AU - Butt, Muhammad

AU - Tabish, Asif

AU - Hanif, Muhammad

AU - Khalid, Muhammad

AU - Ghaffar, Rabia

AU - Rafique, Muhammad

AU - Shawar Kazmi, Syeda

AU - Siraj, Khurram

AU - Hafez, Amal

AU - Abd-Rabboh, Hisham

AU - Zmrhalova, Zuzana

AU - Filonova, Elena

AU - Medvedev, Dmitry

AU - Motola, Martin

N1 - The authors declare financial support was received for the research, authorship, and/or publication of this article. The authors extend their appreciation to the Deanship of Scientific Research at King Khalid University for funding this work through the Large Groups Project under grant number (RGP.2/335/44).

PY - 2023

Y1 - 2023

N2 - In this study, BaZr0.87Y0.1M0.03O3−δ perovskite electrolytes with sintering aids (M = Mn, Co, and Fe) were synthesized by a sustainable approach using spinach powder as a chelating agent and then compared with chemically synthesized BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes for intermediate temperature SOFCs. This is the first example of such a sustainable synthesis of perovskite materials with sintering aids. Structural analysis revealed the presence of a cubic perovskite structure in BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) samples synthesized by both green and conventional chemical methods. No significant secondary phases were observed in the samples synthesized by a sustainable approach. The observed phenomena of plane shift were because of the disparities between ionic radii of the dopants, impurities, and host materials. The surface morphology analysis revealed a denser microstructure for the electrolytes synthesized via green routes due to metallic impurities in the organic chelating agent. The absence of significant impurities was also observed by compositional analysis, while functional groups were identified through Fourier-transform infrared spectroscopy. Conductivity measurements showed that BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes synthesized by oxalic acid have higher conductivities compared to BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes synthesized by the green approach. The button cells employing BaZr0.87Y0.1Co0.03O3−δ electrolytes synthesized by the chemical and green routes achieved peak power densities 344 and 271 mW·cm−2 respectively, suggesting that the novel green route can be applied to synthesize SOFC perovskite materials with minimal environmental impact and without significantly compromising cell performance.

AB - In this study, BaZr0.87Y0.1M0.03O3−δ perovskite electrolytes with sintering aids (M = Mn, Co, and Fe) were synthesized by a sustainable approach using spinach powder as a chelating agent and then compared with chemically synthesized BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes for intermediate temperature SOFCs. This is the first example of such a sustainable synthesis of perovskite materials with sintering aids. Structural analysis revealed the presence of a cubic perovskite structure in BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) samples synthesized by both green and conventional chemical methods. No significant secondary phases were observed in the samples synthesized by a sustainable approach. The observed phenomena of plane shift were because of the disparities between ionic radii of the dopants, impurities, and host materials. The surface morphology analysis revealed a denser microstructure for the electrolytes synthesized via green routes due to metallic impurities in the organic chelating agent. The absence of significant impurities was also observed by compositional analysis, while functional groups were identified through Fourier-transform infrared spectroscopy. Conductivity measurements showed that BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes synthesized by oxalic acid have higher conductivities compared to BaZr0.87Y0.1M0.03O3−δ (M = Mn, Co, and Fe) electrolytes synthesized by the green approach. The button cells employing BaZr0.87Y0.1Co0.03O3−δ electrolytes synthesized by the chemical and green routes achieved peak power densities 344 and 271 mW·cm−2 respectively, suggesting that the novel green route can be applied to synthesize SOFC perovskite materials with minimal environmental impact and without significantly compromising cell performance.

UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=85179304761

UR - https://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=tsmetrics&SrcApp=tsm_test&DestApp=WOS_CPL&DestLinkType=FullRecord&KeyUT=001121801500001

U2 - 10.3389/fchem.2023.1322475

DO - 10.3389/fchem.2023.1322475

M3 - Article

VL - 11

JO - Frontiers in Chemistry

JF - Frontiers in Chemistry

SN - 2296-2646

M1 - 1322475

ER -

ID: 49511687