SiOC and SiBOC polymer-derived glasses show a complex nanostructure in which nanocrystalline -SiC and sp2 C coexists with nanoclusters of amorphous SiO2 or SiO2-B2O3 and with mixed silicon oxycarbide and boron oxycarbide units. The characterization of the nanostructure is performed with a multiple technique approach on SiOC and SiBOC glasses before and after HF etching. The acid attack dissolves the silica-based nanoclusters and allows indirect information on their size and amount to be obtained. By increasing the pyrolysis temperature from 1200 up to 1500 °C the oxide clusters grow in size and amount in both SiOC and SiBOC glasses. Compared to the B-free SiOC glass, SiBOC is more easily etched and develops higher porosity and larger pore size. Boron has also an important effect on the ordering of the sp2 C phase: it leads to thicker sp2 C nanocrystals. This effect is remarkable because it starts at low temperature (1500 °C) compared to the usual temperature, 1800 °C, reported in the literature for different forms of nanocrystalline carbon. Raman analysis of SiBOC glasses pyrolyzed at 1500 °C clearly shows the presence of the D′ band at 1617 cm-1. From this experimental result it is postulated that B enters into the graphene layers forming BC3 units. Finally, the shift toward lower wavenumbers of the Raman spectra recorded on SiOC and SiBOC glasses after etching seems to reveal a high compressive stress acting along the basal sp2 C planes of the graphite nanocrystals.

New Insights on the high temperature nanostructure evolution of SiOC and B-doped SiBOC Polymer-derived Glasses

MARIOTTO, Gino;
2007-01-01

Abstract

SiOC and SiBOC polymer-derived glasses show a complex nanostructure in which nanocrystalline -SiC and sp2 C coexists with nanoclusters of amorphous SiO2 or SiO2-B2O3 and with mixed silicon oxycarbide and boron oxycarbide units. The characterization of the nanostructure is performed with a multiple technique approach on SiOC and SiBOC glasses before and after HF etching. The acid attack dissolves the silica-based nanoclusters and allows indirect information on their size and amount to be obtained. By increasing the pyrolysis temperature from 1200 up to 1500 °C the oxide clusters grow in size and amount in both SiOC and SiBOC glasses. Compared to the B-free SiOC glass, SiBOC is more easily etched and develops higher porosity and larger pore size. Boron has also an important effect on the ordering of the sp2 C phase: it leads to thicker sp2 C nanocrystals. This effect is remarkable because it starts at low temperature (1500 °C) compared to the usual temperature, 1800 °C, reported in the literature for different forms of nanocrystalline carbon. Raman analysis of SiBOC glasses pyrolyzed at 1500 °C clearly shows the presence of the D′ band at 1617 cm-1. From this experimental result it is postulated that B enters into the graphene layers forming BC3 units. Finally, the shift toward lower wavenumbers of the Raman spectra recorded on SiOC and SiBOC glasses after etching seems to reveal a high compressive stress acting along the basal sp2 C planes of the graphite nanocrystals.
2007
Polymer-derived Glasses; SiOC and SiBOC glasses; nanostructure evolution vs. temperature
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11562/311754
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