Master Thesis
Several Master Theses are available at the CRECK Modeling Lab. Please click on the links below for further information.
2. Development of a state-of-the-art model for hydrogen combustion
4. Design of a biomass pyrolytic stove for cooking purposes in underdeveloped countries
6. Numerical modeling of Chemical Vapor Infiltration (CVI) reactors for carbon disk brakes production
7. Chemical recycling of plastics via pyrolysis and gasification
8. Thermal degradation of biomasses: update of a detailed kinetic model from experimental data
9. E-fuels for the energy transition: kinetic modeling and applications
10. Molecular modelling of liquid phase chemical reactions
11. Modeling the growth of polycyclic aromatic hydrocarbons (PAHs) from hydrocarbon pyrolysis
12. Carbonaceous nanoparticles: modeling primary particle formation for electronic device applications
13. Nitrogen oxides formation from H2 and H2/CH4 mixtures
14. Theoretical investigation of relevant NOx/e-Fuels interactions
15. Modelling the e-fuel/NOx interactions in internal combustion engines
16. Optimization of jet-fuel surrogates
17. Reaction class based kinetic mechanism optimization for aromatic hydrocarbons
18. Kinetic modeling of C4 alkenes pyrolysis and oxidation
19. From small to large: rate rule development for aromatic hydrocarbons additions
20. Exotic oxidation reactions of unsaturated rings
21. Multi-modal flame structure under autoignitive conditions
22. Enhancement of experimental and numerical data through Machine Learning
23. Extension and optimization of reactive flow capabilities in the Basilisk framework
24. Flashback limits of Hydrogen premixed laminar flames
25. Numerical Investigation of multi-modal combustion regimes in partially premixed flames
26. Kinetic modelling for the prediction of biochar yield from conventional and unusual biomass feedstock
27. Fuel effects on emissions characteristics and flame stability of Sustainable Aviation Fuels
28. Development of highly reduced kinetic models for Real Fuels