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Phase relationships and thermal behavior of one-pot synthesized dual-phase BaCe0.5Fe0.5O3–δ composites. / Tarutina, Liana; Kuznetsova, Polina; Skutina, Lubov; Мурашкина, Анна Андреевна; Medvedev, Dmitry.

в: Ceramics International, 21.11.2024.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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Tarutina, Liana ; Kuznetsova, Polina ; Skutina, Lubov ; Мурашкина, Анна Андреевна ; Medvedev, Dmitry. / Phase relationships and thermal behavior of one-pot synthesized dual-phase BaCe0.5Fe0.5O3–δ composites. в: Ceramics International. 2024.

BibTeX

@article{72a0166bcf1e49ce97bcff024b3a89e4,
title = "Phase relationships and thermal behavior of one-pot synthesized dual-phase BaCe0.5Fe0.5O3–δ composites",
abstract = "The synthesis of self-assembled composite materials via a one-pot technique offers a promising strategy for designing modernized electrodes for use in solid oxide electrochemical cells based on both oxygen-ionic and proton-conducting electrolytes. Within the present work, a BaCe0.5Fe0.5O3–δ composite (extensively investigated in the literature as a triple conductor) was prepared as both dense and porous ceramics. The thermal properties of these materials were subsequently characterized via a range of complimentary techniques, including high-temperature X-ray diffraction, thermogravimetry, and dilatometry analyses. The employed methods allow for the refinement of the compositions for both Ce- and Fe-enriched phases, as well as the determination of the thermal expansion behaviors of both the basic components and the composite as a whole. The experimental results demonstrate that the Ce- and Fe-based phases exhibit markedly disparate thermomechanical responses, which represents a significant limitation for the joint application of BaCe0.5Fe0.5O3–δ-derived electrodes with a range of electrolyte representatives. While the thermomechanical discrepancy can be reduced for the porous state of the electrodes, greater attention should be paid to the microstructural integrity of such electrodes and the quality of the electrolyte/electrode interface under long-term and cycling operating conditions. Therefore, this work provides complementary information on the various functional properties of dual-phase BaCe0.5Fe0.5O3–δ composites.",
keywords = "Composite materials, One-pot synthesis, PCFC, Proton-conducting electrolytes, Thermal expansion",
author = "Liana Tarutina and Polina Kuznetsova and Lubov Skutina and Мурашкина, {Анна Андреевна} and Dmitry Medvedev",
year = "2024",
month = nov,
day = "21",
doi = "10.1016/j.ceramint.2024.11.324",
language = "English",
journal = "Ceramics International",
issn = "0272-8842",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Phase relationships and thermal behavior of one-pot synthesized dual-phase BaCe0.5Fe0.5O3–δ composites

AU - Tarutina, Liana

AU - Kuznetsova, Polina

AU - Skutina, Lubov

AU - Мурашкина, Анна Андреевна

AU - Medvedev, Dmitry

PY - 2024/11/21

Y1 - 2024/11/21

N2 - The synthesis of self-assembled composite materials via a one-pot technique offers a promising strategy for designing modernized electrodes for use in solid oxide electrochemical cells based on both oxygen-ionic and proton-conducting electrolytes. Within the present work, a BaCe0.5Fe0.5O3–δ composite (extensively investigated in the literature as a triple conductor) was prepared as both dense and porous ceramics. The thermal properties of these materials were subsequently characterized via a range of complimentary techniques, including high-temperature X-ray diffraction, thermogravimetry, and dilatometry analyses. The employed methods allow for the refinement of the compositions for both Ce- and Fe-enriched phases, as well as the determination of the thermal expansion behaviors of both the basic components and the composite as a whole. The experimental results demonstrate that the Ce- and Fe-based phases exhibit markedly disparate thermomechanical responses, which represents a significant limitation for the joint application of BaCe0.5Fe0.5O3–δ-derived electrodes with a range of electrolyte representatives. While the thermomechanical discrepancy can be reduced for the porous state of the electrodes, greater attention should be paid to the microstructural integrity of such electrodes and the quality of the electrolyte/electrode interface under long-term and cycling operating conditions. Therefore, this work provides complementary information on the various functional properties of dual-phase BaCe0.5Fe0.5O3–δ composites.

AB - The synthesis of self-assembled composite materials via a one-pot technique offers a promising strategy for designing modernized electrodes for use in solid oxide electrochemical cells based on both oxygen-ionic and proton-conducting electrolytes. Within the present work, a BaCe0.5Fe0.5O3–δ composite (extensively investigated in the literature as a triple conductor) was prepared as both dense and porous ceramics. The thermal properties of these materials were subsequently characterized via a range of complimentary techniques, including high-temperature X-ray diffraction, thermogravimetry, and dilatometry analyses. The employed methods allow for the refinement of the compositions for both Ce- and Fe-enriched phases, as well as the determination of the thermal expansion behaviors of both the basic components and the composite as a whole. The experimental results demonstrate that the Ce- and Fe-based phases exhibit markedly disparate thermomechanical responses, which represents a significant limitation for the joint application of BaCe0.5Fe0.5O3–δ-derived electrodes with a range of electrolyte representatives. While the thermomechanical discrepancy can be reduced for the porous state of the electrodes, greater attention should be paid to the microstructural integrity of such electrodes and the quality of the electrolyte/electrode interface under long-term and cycling operating conditions. Therefore, this work provides complementary information on the various functional properties of dual-phase BaCe0.5Fe0.5O3–δ composites.

KW - Composite materials

KW - One-pot synthesis

KW - PCFC

KW - Proton-conducting electrolytes

KW - Thermal expansion

UR - https://www.mendeley.com/catalogue/ab3e740d-5a4a-3010-8a2a-5c13fd001fe3/

U2 - 10.1016/j.ceramint.2024.11.324

DO - 10.1016/j.ceramint.2024.11.324

M3 - Article

JO - Ceramics International

JF - Ceramics International

SN - 0272-8842

ER -

ID: 127597752