Maintaining pronounced proton transportation of solid oxides prepared with a sintering additive

Proton-conducting electrolytes (PCEs) have led to significant advances in the fields of solid-state ionics, energy conversion and high-temperature electrochemistry, providing the basis of various solid oxide devices that demonstrate outstanding performance and efficiency. Although the proton transpo...

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Bibliographic Details
Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2021-07, Vol.9 (25), p.14553-14565
Main Authors: Mineev, Alexey M, Zvonareva, Inna A, Medvedev, Dmitry A, Shao, Zongping
Format: Article
Language:English
Subjects:
Additives
Conduction
Electrochemistry
Electrolytes
Electrolytic cells
Energy conversion
Fabrication
Gas tightness
Grain boundaries
High temperature
Impurities
Ion transport
Localization
Protons
Refractory materials
Sintering
Thin films
Water uptake
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Summary:Proton-conducting electrolytes (PCEs) have led to significant advances in the fields of solid-state ionics, energy conversion and high-temperature electrochemistry, providing the basis of various solid oxide devices that demonstrate outstanding performance and efficiency. Although the proton transport of PCEs has an undeniable advantage over the oxygen-ion transport of conventional complex oxide approaches, the refractory nature of these materials presents significant challenges for their fabrication in the form of thin films. In order to mitigate sintering conditions for multilayered PCE structures (single cells), various additives have been used. However, other fundamental and technological issues arise in this connection, including the localization of such introduced impurities near grain boundaries resulting in blocked proton transportation. The present article reports a general strategy for effectively sintering PCE-based refractory materials while maintaining their hydrogen transportation, using a BaSn 0.8 Sc 0.2 O 3− δ model compound due to its significant water uptake even at high levels of acceptor doping. This strategy, as shown in a comprehensive analysis of corresponding experimental results, proposes a CuO sintering additive in low amounts, sufficient for achieving a dense state with no adverse effects on protonic conduction. The reported findings can be applied for scalable preparation of gas tight PCEs at reduced sintering temperatures for various electrochemical purposes. This work reports key findings allowing a dense proton-conducting ceramic to be produced with a CuO sintering additive. A selection of this additive in low amounts results in materials exhibiting full proton capability and high ionic conductivity.
ISSN:2050-7488
2050-7496
DOI:10.1039/d1ta03399a