Niu, Zi-Bo ; Li, Daxin ; Jia, Dechang ; Yang, Zhihua ; Lin, Kunpeng ; Wang, Yan ; Colombo, Paolo ; Riedel, Ralf ; Zhou, Yu (2024)
Fabrication of dense SiBCN monolith at a lower temperature and its high-temperature performance.
In: Journal of Advanced Ceramics, 13 (8)
doi: 10.26599/JAC.2024.9220929
Artikel, Bibliographie
Kurzbeschreibung (Abstract)
In this study, a crack-free pyrolysis process of partially cured precursor powder compacts was developed to prepare dense silicon boron carbonitride (SiBCN) monoliths at much lower temperatures (1300 degrees C), thereby circumventing the challenges of sintering densification (> 1800 degrees C). Unlike the elastic fracture in over-cured precursors or the viscoelastic deformation in under-cured precursors, the partially cured precursor, exhibiting elastic-plastic deformation behavior, facilitates limited nanoscale pore formation in a dense structure, achieving a balance between crack-free pyrolysis and densification. Compared to SiBCN derived from the over-cured precursor (sigma = similar to 159 MPa, K-IC = 1.9 MPa center dot m(1/2), Vickers hardness (HV) = 7.8 GPa, and E = 122 GPa), the resulting SiBCN monolith exhibited significantly improved mechanical properties (sigma = similar to 304 MPa, K-IC = 3.7 MPa center dot m(1/2), HV = 10.6 GPa, and E = 161 GPa) and oxidation resistance. In addition, this study investigated the high-temperature performance of SiBCN monoliths, including crystallization and oxidation, and determined the oxidation kinetics induced by pore structure healing and the different oxidation mechanisms of Si-C-N and B-C-N clusters in the amorphous structure. Due to its unique composition and structure, the SiBCN ceramic oxide layer exhibits exceptional self-healing effects on repairing the nanoporous system in the initial stage and shows outstanding high-temperature stability during prolonged oxidation, mitigating adverse effects from bubble formation and crystallization. Due to the nanoporous structure, the oxidation rate is initially controlled by gas diffusion following a linear law before transitioning to oxide layer diffusion characterized by a parabolic law. Finally, due to different valence bond configurations, Si-C-N transforms into an amorphous SiCNO structure after phase separation, unlike the nucleation and growth of residual B-N-C.
| Typ des Eintrags: | Artikel |
|---|---|
| Erschienen: | 2024 |
| Autor(en): | Niu, Zi-Bo ; Li, Daxin ; Jia, Dechang ; Yang, Zhihua ; Lin, Kunpeng ; Wang, Yan ; Colombo, Paolo ; Riedel, Ralf ; Zhou, Yu |
| Art des Eintrags: | Bibliographie |
| Titel: | Fabrication of dense SiBCN monolith at a lower temperature and its high-temperature performance |
| Sprache: | Englisch |
| Publikationsjahr: | August 2024 |
| Verlag: | Tsinghua University Press |
| Titel der Zeitschrift, Zeitung oder Schriftenreihe: | Journal of Advanced Ceramics |
| Jahrgang/Volume einer Zeitschrift: | 13 |
| (Heft-)Nummer: | 8 |
| DOI: | 10.26599/JAC.2024.9220929 |
| Kurzbeschreibung (Abstract): | In this study, a crack-free pyrolysis process of partially cured precursor powder compacts was developed to prepare dense silicon boron carbonitride (SiBCN) monoliths at much lower temperatures (1300 degrees C), thereby circumventing the challenges of sintering densification (> 1800 degrees C). Unlike the elastic fracture in over-cured precursors or the viscoelastic deformation in under-cured precursors, the partially cured precursor, exhibiting elastic-plastic deformation behavior, facilitates limited nanoscale pore formation in a dense structure, achieving a balance between crack-free pyrolysis and densification. Compared to SiBCN derived from the over-cured precursor (sigma = similar to 159 MPa, K-IC = 1.9 MPa center dot m(1/2), Vickers hardness (HV) = 7.8 GPa, and E = 122 GPa), the resulting SiBCN monolith exhibited significantly improved mechanical properties (sigma = similar to 304 MPa, K-IC = 3.7 MPa center dot m(1/2), HV = 10.6 GPa, and E = 161 GPa) and oxidation resistance. In addition, this study investigated the high-temperature performance of SiBCN monoliths, including crystallization and oxidation, and determined the oxidation kinetics induced by pore structure healing and the different oxidation mechanisms of Si-C-N and B-C-N clusters in the amorphous structure. Due to its unique composition and structure, the SiBCN ceramic oxide layer exhibits exceptional self-healing effects on repairing the nanoporous system in the initial stage and shows outstanding high-temperature stability during prolonged oxidation, mitigating adverse effects from bubble formation and crystallization. Due to the nanoporous structure, the oxidation rate is initially controlled by gas diffusion following a linear law before transitioning to oxide layer diffusion characterized by a parabolic law. Finally, due to different valence bond configurations, Si-C-N transforms into an amorphous SiCNO structure after phase separation, unlike the nucleation and growth of residual B-N-C. |
| Freie Schlagworte: | silicon boron carbonitride (SiBCN) ceramics, crack-free pyrolysis, amorphous structure, oxidation mechanisms, kinetic law |
| Fachbereich(e)/-gebiet(e): | 11 Fachbereich Material- und Geowissenschaften 11 Fachbereich Material- und Geowissenschaften > Materialwissenschaft 11 Fachbereich Material- und Geowissenschaften > Materialwissenschaft > Werkstofftechnik und Ressourcenmanagement |
| Hinterlegungsdatum: | 20 Jan 2025 06:44 |
| Letzte Änderung: | 20 Jan 2025 10:24 |
| PPN: | 52542184X |
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