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Radiation-Thermal Sintering of Oxide and Composite Materials for Hydrogen Energy by Electron Beam: A Review Обзор

Журнал Electrochemical Materials and Technologies
, E-ISSN: 2949-0561
Вых. Данные Год: 2025, Том: 4, Номер: 4, Номер статьи : 20254062, Страниц : 31 DOI: 10.15826/elmattech.2025.4.062
Ключевые слова radiation-thermal sintering; electron beam; complex oxides; solid oxide fuel cells; permselective membranes
Авторы Eremeev Nikita 1 , Bespalko Yulia 1 , Mikhailenko Mikhail 2 , Korobeynikov Mikhail 3 , Sadykov Vladislav 1
Организации
1 Federal Research Center Boreskov Institute of Catalysis SB RAS, Novosibirsk 630090, Russia
2 Institute of Solid State Chemistry and Mechanochemistry SB RAS, Novosibirsk 630128, Russia
3 Budker Institute of Nuclear Physics SB RAS, Novosibirsk 630090, Russia

Информация о финансировании (1)

1 Российский научный фонд 23-73-00045

Реферат: The scaling of hydrogen technologies – from production and storage to utilization – is critically dependent on advanced manufacturing methods for key components such as catalytic reactors, permselective membranes, and electrochemical cells. The synthesis and processing of high-performance ceramic materials for these devices necessitates innovative sintering approaches. Radiation-thermal sintering (RTS) employing high-energy electron beams offers a viable alternative to conventional sintering methods, facilitating the expeditious fabrication of ceramics with tailored mechanical, morphological, structural, and transport properties. Although techniques such as spark plasma and microwave sintering have been the subject of extensive reviews, RTS remains comparatively under-explored. This review comprehensively examines the application of RTS for engineering functional ceramics – including perovskites, Ruddlesden–Popper phases, fluorites, garnets, and magnetoplumbites. These ceramics are essential for solid oxide cells, oxygen/hydrogen separation membranes, catalysts for fuel transformation into hydrogen and syngas, and other applications. The current understanding of how RTS influences material properties and device performance is demonstrated. Furthermore, critical research gaps are identified, particularly concerning the impact of electron irradiation on defect equilibria, ionic conductivity, and long-term functional stability. This underscores the necessity for focused studies to fully harness RTS for the fabrication of next-generation energy devices.
Библиографическая ссылка: Eremeev N. , Bespalko Y. , Mikhailenko M. , Korobeynikov M. , Sadykov V.
Radiation-Thermal Sintering of Oxide and Composite Materials for Hydrogen Energy by Electron Beam: A Review
Electrochemical Materials and Technologies. 2025. V.4. N4. 20254062 :1-31. DOI: 10.15826/elmattech.2025.4.062
Даты:
Поступила в редакцию: 15 сент. 2025 г.
Принята к публикации: 7 окт. 2025 г.
Опубликована online: 20 окт. 2025 г.
Идентификаторы БД: Нет идентификаторов
Цитирование в БД: Пока нет цитирований
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