Date of Award
2024-12-01
Degree Name
Master of Science
Department
Mechanical Engineering
Advisor(s)
Evgeny Shafirovich
Abstract
The growing demand for hydrogen as a clean energy carrier highlights the need for its alternative production method with reduced CO₂ emissions. Microwave-assisted thermocatalytic dehydrogenation of fossil fuels offers a promising solution for clean hydrogen production, with FeAlxOy nanocomposites acting as efficient catalysts due to their thermal stability, catalytic activity, and microwave-absorption properties. FeAlxOy nanocomposites, fabricated by solution combustion synthesis (SCS), have shown good microwave-absorption and catalytic properties. However, the effects of synthesis parameters such as fuel type and Fe:Al molar ratio on the SCS process and properties of the final material are not well understood. The SCS process involves vaporization of water, thermal decomposition of the mixture components, and oxidation – reduction reactions. In the present work, thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) were utilized to study the SCS mechanism, with a focus on understanding decomposition processes. TGA provided insights into the thermal stability and mass loss profiles of the mixtures, while DSC quantified the heat release and identified reaction onset temperatures. Results demonstrated that the choice of fuel significantly influenced the thermal behavior and properties of FeAlxOy nanocomposites. Glycine-based mixtures exhibited superior thermal stability and complete decomposition in a single step with high heat release compared to citric acid-based mixtures, which required higher synthesis temperatures and experienced slower, two-step decomposition processes. These findings emphasize the effectiveness of glycine-fueled SCS in producing thermally stable and catalytically active FeAlxOy nanocomposites.
Language
en
Provenance
Recieved from ProQuest
Copyright Date
2024-12-01
File Size
42 p.
File Format
application/pdf
Rights Holder
Laura Alejandra Martinez Espinoza
Recommended Citation
Martinez Espinoza, Laura Alejandra, "Thermal analysis of combustion synthesis of FeAlxOy catalysts for dehydrogenation of fossil fuels" (2024). Open Access Theses & Dissertations. 4267.
https://scholarworks.utep.edu/open_etd/4267