A study of pyrolysis reaction mechanisms for two different sustainable aviation fuels certificated by Civil Aviation Administration of China

Sustainable aviation fuel (SAF), particularly hydrotreated esters and fatty acids (HEFA) derived from waste cooking oil (WCO), is a realistic and potential pathway to realize the target of “Fly Net Zero” for the aviation industry. To develop reaction mechanisms of SAF suitable for combustor simulations, two different SAFs (named SAF1 and SAF2) synthesized from WCO and certificated by Civil Aviation Administration of China (CAAC) were investigated. The detailed compositional analyses of these two SAFs were executed via gas chromatography-mass spectrometry (GC-MS) technique, and the results were used to construct surrogate models. The pyrolysis and oxidation experiments were performed in a flow reactor at 1000 K and an atmospheric pressure to obtain the speciation data for the two SAFs. The Hybrid Chemistry (HyChem) approach was employed to develop reaction mechanisms of the two SAFs. A multi-objective genetic algorithm, NSGA-II, was utilized to determine the three Arrhenius coefficients of the seven lumped reactions. Both HyChem models were successfully validated by the experimental data. The speciation data and global combustion parameters were accurately predicted by HyChem models for these two SAFs. Finally, sensitivity analysis revealed the similar effects of the seven lumped reactions on ignition delay time (IDT) for the two SAFs. R2 (fuel + H), R4 (fuel + OH), and R5 (fuel + O₂) play important roles in the system reactivity, while R6 (fuel + HO₂) and R7 (fuel + O) have negligible influence on IDT predictions for all tested conditions.