Current and further trajectories in designing functional materials for solid oxide electrochemical cells: A review of other reviews

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Current and further trajectories in designing functional materials for solid oxide electrochemical cells: A review of other reviews. / Baratov, Stanislav ; Filonova, Elena ; Ivanova, Anastasiya et al.
In: Journal of Energy Chemistry, Vol. 94, 01.07.2024, p. 302-331.

Research output: Contribution to journal › Article › peer-review

BibTeX

@article{e1f7d198318d43939a8d700512fdac1e,

title = "Current and further trajectories in designing functional materials for solid oxide electrochemical cells: A review of other reviews",

abstract = "Complex oxides are an important class of materials with enormous potential for electrochemical applications. Depending on their composition and structure, such complex oxides can exhibit either a single conductivity (oxygen-ionic or protonic, or n-type, or p-type electronic) or a combination thereof generating distinct dual-conducting or even triple-conducting materials. These properties enable their use as diverse functional materials for solid oxide fuel cells, solid oxide electrolysis cells, permeable membranes, and gas sensors. The literature review shows that the field of solid oxide materials and related electrochemical cells has a significant level of research engagement, with over 8,000 publications published since 2020. The manual analysis of such a large volume of material is challenging. However, by examining the review articles, it is possible to identify key patterns, recent achievements, prospects, and remaining obstacles. To perform such an analysis, the present article provides, for the first time, a comprehensive summary of previous review publications that have been published since 2020, with a special focus on solid oxide materials and electrochemical systems. Thus, this study provides an important reference for researchers specializing in the fields of solid state ionics, high-temperature electrochemistry, and energy conversion technologies.",

author = "Stanislav Baratov and Elena Filonova and Anastasiya Ivanova and Hanif, {Muhammad Bilal} and Muneeb Irshad and Khan, {Muhammad Zubair} and Martin Motola and Sajid Rauf and Dmitry Medvedev",

note = "Muhammad BilalHanif is currently employed as a Senior Researcher at the Department of Inorganic Chemistry, Faculty of Natural Sciences, Comenius University in Bratislava, Slovakia. Additionally, he collaborates with the Polish Academy of Sciences in Krakow, Poland, under the guidance of Dr. hab. Micha{\l} Mosia{\l}ek. Recognizing his achievements, he has been honored with the Young Scientists award from XJTU, China, and has received the UK grant for the years 2021–2024 at Comenius University Bratislava, Slovakia. His research primarily focuses on solid oxide fuel cells, solid oxide electrolysis cells, and solid-state batteries for energy conversion applications. This work was prepared within the framework of the budgetary plans of the Hydrogen Energy Laboratory (Ural Federal University) and Institute of High Temperature Electrochemistry (IHTE).",

year = "2024",

month = jul,

day = "1",

doi = "10.1016/j.jechem.2024.02.047",

language = "English",

volume = "94",

pages = "302--331",

journal = "Journal of Energy Chemistry",

issn = "2095-4956",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Current and further trajectories in designing functional materials for solid oxide electrochemical cells: A review of other reviews

AU - Baratov, Stanislav

AU - Filonova, Elena

AU - Ivanova, Anastasiya

AU - Hanif, Muhammad Bilal

AU - Irshad, Muneeb

AU - Khan, Muhammad Zubair

AU - Motola, Martin

AU - Rauf, Sajid

AU - Medvedev, Dmitry

N1 - Muhammad BilalHanif is currently employed as a Senior Researcher at the Department of Inorganic Chemistry, Faculty of Natural Sciences, Comenius University in Bratislava, Slovakia. Additionally, he collaborates with the Polish Academy of Sciences in Krakow, Poland, under the guidance of Dr. hab. Michał Mosiałek. Recognizing his achievements, he has been honored with the Young Scientists award from XJTU, China, and has received the UK grant for the years 2021–2024 at Comenius University Bratislava, Slovakia. His research primarily focuses on solid oxide fuel cells, solid oxide electrolysis cells, and solid-state batteries for energy conversion applications. This work was prepared within the framework of the budgetary plans of the Hydrogen Energy Laboratory (Ural Federal University) and Institute of High Temperature Electrochemistry (IHTE).

PY - 2024/7/1

Y1 - 2024/7/1

N2 - Complex oxides are an important class of materials with enormous potential for electrochemical applications. Depending on their composition and structure, such complex oxides can exhibit either a single conductivity (oxygen-ionic or protonic, or n-type, or p-type electronic) or a combination thereof generating distinct dual-conducting or even triple-conducting materials. These properties enable their use as diverse functional materials for solid oxide fuel cells, solid oxide electrolysis cells, permeable membranes, and gas sensors. The literature review shows that the field of solid oxide materials and related electrochemical cells has a significant level of research engagement, with over 8,000 publications published since 2020. The manual analysis of such a large volume of material is challenging. However, by examining the review articles, it is possible to identify key patterns, recent achievements, prospects, and remaining obstacles. To perform such an analysis, the present article provides, for the first time, a comprehensive summary of previous review publications that have been published since 2020, with a special focus on solid oxide materials and electrochemical systems. Thus, this study provides an important reference for researchers specializing in the fields of solid state ionics, high-temperature electrochemistry, and energy conversion technologies.

AB - Complex oxides are an important class of materials with enormous potential for electrochemical applications. Depending on their composition and structure, such complex oxides can exhibit either a single conductivity (oxygen-ionic or protonic, or n-type, or p-type electronic) or a combination thereof generating distinct dual-conducting or even triple-conducting materials. These properties enable their use as diverse functional materials for solid oxide fuel cells, solid oxide electrolysis cells, permeable membranes, and gas sensors. The literature review shows that the field of solid oxide materials and related electrochemical cells has a significant level of research engagement, with over 8,000 publications published since 2020. The manual analysis of such a large volume of material is challenging. However, by examining the review articles, it is possible to identify key patterns, recent achievements, prospects, and remaining obstacles. To perform such an analysis, the present article provides, for the first time, a comprehensive summary of previous review publications that have been published since 2020, with a special focus on solid oxide materials and electrochemical systems. Thus, this study provides an important reference for researchers specializing in the fields of solid state ionics, high-temperature electrochemistry, and energy conversion technologies.

UR - http://www.scopus.com/inward/record.url?partnerID=8YFLogxK&scp=85187982847

UR - https://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=tsmetrics&SrcApp=tsm_test&DestApp=WOS_CPL&DestLinkType=FullRecord&KeyUT=001218472100001

U2 - 10.1016/j.jechem.2024.02.047

DO - 10.1016/j.jechem.2024.02.047

M3 - Article

VL - 94

SP - 302

EP - 331

JO - Journal of Energy Chemistry

JF - Journal of Energy Chemistry

SN - 2095-4956

ER -

ID: 55351806