What question did this study set out to answer?

The aim is to investigate the crystallization process of a mullite precursor synthesized through combustion.

March 1, 2026

Crystallization of a Combustion-Derived Mullite Precursor

Key Points

The aim is to investigate the crystallization process of a mullite precursor synthesized through combustion.
Synthesis of mullite precursor via combustion of a xerogel mixture
Characterization through thermal analysis, X-ray diffraction, IR spectroscopy, and NMR
Heat treatment at 1100 °C and 1200 °C to observe phase transformation
Estimation of effective activation energy from thermal analysis at varied heating rates
The precursor was initially amorphous before crystallization upon heating
Well-crystallized single-phase mullite formed at 1200 °C
The combustion product contained different AlO groups
Effective activation energy for mullite crystallization was estimated based on thermal analysis

Abstract

A mullite precursor was synthesized via combustion of a xerogel obtained from a mixture of aluminum nitrate, highly dispersed silica (AEROSIL), urea as the fuel (reducing agent), and hydrogen peroxide as an auxiliary additive. The crystallization process of the precursor — its transformation into mullite 3AlO·2SiO — was studied by thermal analysis, X- ray diffraction, IR spectroscopy, and NMR. The synthesized powder was amorphous and crystallized upon heat treatment at 1100 °C. Firing at 1200 °C yielded well-crystallized single-phase mullite. The combustion product contained AlO, AlO, and AlO groups. Using thermal analysis of the precursor at different heating rates, the effective activation energy of mullite crystallization was estimated from the positions of the exothermic peaks corresponding to this transition.

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Crystallization of a Combustion-Derived Mullite Precursor

Key Points

Abstract

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