Structure and Thermodynamics of Silicon Oxycarbide Polymer-Derived Ceramics with and without Mixed-Bonding

Silicon oxycarbides synthesized through a conventional polymeric route show characteristic nanodomains that consist of sp2 hybridized carbon, tetrahedrally coordinated SiO4, and tetrahedrally coordinated silicon with carbon substitution for oxygen, called “mixed bonds.” Here we synthesize two precer...

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Bibliographic Details
Published in:Materials 2021-07, Vol.14 (15), p.4075
Main Authors: Sugie, Casey, Navrotsky, Alexandra, Lauterbach, Stefan, Kleebe, Hans-Joachim, Mera, Gabriela
Format: Article
Language:English
Subjects:
Carbon
Ceramic bonding
Ceramics
Cristobalite
Crystal structure
Crystallinity
Enthalpy
Heat of formation
Heat of solution
High temperature
Hydroxyl groups
Interfacial bonding
Molten salts
NMR
NMR spectroscopy
Nuclear magnetic resonance
Oxycarbides
Polymers
Precursors
Pyrolysis
Raman spectra
Silicon carbide
Silicon dioxide
Spectrum analysis
Tetrahedra
Transmission electron microscopy
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Summary:Silicon oxycarbides synthesized through a conventional polymeric route show characteristic nanodomains that consist of sp2 hybridized carbon, tetrahedrally coordinated SiO4, and tetrahedrally coordinated silicon with carbon substitution for oxygen, called “mixed bonds.” Here we synthesize two preceramic polymers possessing both phenyl substituents as unique organic groups. In one precursor, the phenyl group is directly bonded to silicon, resulting in a SiOC polymer-derived ceramic (PDC) with mixed bonding. In the other precursor, the phenyl group is bonded to the silicon through Si-O-C bridges, which results in a SiOC PDC without mixed bonding. Radial breathing-like mode bands in the Raman spectra reveal that SiOC PDCs contain carbon nanoscrolls with spiral-like rolled-up geometry and open edges at the ends of their structure. Calorimetric measurements of the heat of dissolution in a molten salt solvent show that the SiOC PDCs with mixed bonding have negative enthalpies of formation with respect to crystalline components (silicon carbide, cristobalite, and graphite) and are more thermodynamically stable than those without. The heats of formation from crystalline SiO2, SiC, and C of SiOC PDCs without mixed bonding are close to zero and depend on the pyrolysis temperature. Solid state MAS NMR confirms the presence or absence of mixed bonding and further shows that, without mixed bonding, terminal hydroxyls are bound to some of the Si-O tetrahedra. This study indicates that mixed bonding, along with additional factors, such as the presence of terminal hydroxyl groups, contributes to the thermodynamic stability of SiOC PDCs.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma14154075