期刊
JOURNAL OF MATERIALS SCIENCE
卷 57, 期 28, 页码 13264-13286出版社
SPRINGER
DOI: 10.1007/s10853-022-07467-3
关键词
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资金
- Deutsche Forschungsgemeinschaft (DFG) [WE4972/2, GRK2495F]
- Slovenian Research Agency [J2-3058]
- SLO-DE bilateral project [J2-3058, BI-DE/20-21-012, P2-0105]
- European Union [101031415]
- JSPS KAKENHI [JP19KK0124]
- Marie Curie Actions (MSCA) [101031415] Funding Source: Marie Curie Actions (MSCA)
The room temperature aerosol deposition method shows great potential for the rapid deposition of ceramic thick films. However, challenges remain in terms of electrical conductivity and internal stresses in as-deposited films. In this study, a novel technique using a sacrificial water-soluble buffer layer was employed to fabricate freestanding ceramic thick films, allowing for direct observation of the film's properties. The temperature-dependent chemical and structural relaxation phenomena in freestanding BaTiO3 films were investigated, revealing the influence of lattice defects and introducing insight into the origin of high room temperature conductivity in as-deposited films.
The room temperature aerosol deposition method is especially promising for the rapid deposition of ceramic thick films, making it interesting for functional components in energy, mobility, and telecommunications applications. Despite this, a number of challenges remain, such as an enhanced electrical conductivity and internal residual stresses in as-deposited films. In this work, a novel technique that integrates a sacrificial water-soluble buffer layer was used to fabricate freestanding ceramic thick films, which allows for direct observation of the film without influence of the substrate or prior thermal treatment. Here, the temperature-dependent chemical and structural relaxation phenomena in freestanding BaTiO3 films were directly investigated by characterizing the thermal expansion properties and temperature-dependent crystal structure as a function of oxygen partial pressure, where a clear nonlinear, hysteretic contraction was observed during heating, which is understood to be influenced by lattice defects. As such, aliovalent doping and atmosphere-dependent annealing experiments were used to demonstrate the influence of local chemical redistribution and oxygen vacancies on the thermal expansion, leading to insight into the origin of the high room temperature conductivity of as-deposited films as well as greater insight into the influence of the induced chemical, structural, and microstructural changes in room temperature deposited functional ceramic thick films. [GRAPHICS] .
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