What question did this study set out to answer?

This research aims to investigate how high-purity xerogel SiO2 changes structurally when heated in different gases.

February 26, 2026

Structural Transformations of High-Purity Xerogel SiO2 in the Temperature Range of 300–1200°C

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This research aims to investigate how high-purity xerogel SiO2 changes structurally when heated in different gases.
Used synchronous thermal analysis including TGA–DSC to monitor changes during heating.
Conducted chromatography–mass spectrometry to analyze organic content.
Performed controlled combustion in oxygen to observe component removal.
Measured porosity, specific surface area, and density at varying temperatures.
Analyzed Raman spectra to study structural integrity.
Organic components are mostly removed between 400–600°C, but some remain until 1050°C.
At temperatures of 1000–1200°C, the xerogel's pores close, indicating structural compaction.
The structural network transitions to a glassy state at higher temperatures.

Resumen

Based on synchronous thermal analysis (TGA–DSC), the structural transformations of high-purity synthetic xerogel SiO2 is studied during heat treatment in various media (argon, air, and oxygen) in the temperature range of 300–1200°C. Chromatography–mass spectrometry and controlled combustion of the sample in a stream of oxygen show that the removal of organic components occurs predominantly in the temperature range of 400–600°C, but continues up to 1050°C. Analysis of porosity, specific surface area, apparent density, and Raman spectra show that in the range of 1000–1200°C, pores are closed and the structural network of the SiO2 xerogel is compacted with transition to a glassy state.

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Structural Transformations of High-Purity Xerogel SiO2 in the Temperature Range of 300–1200°C

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