Analytical Pyrolysis of Pinus radiata and Eucalyptus globulus: Effects of Microwave Pretreatment on Pyrolytic Vapours Composition

Pinus radiata (PR) and Eucalyptus globulus (EG) are the most planted species in Chile. This research aims to evaluate the pyrolysis behaviour of PR and EG from the B & iacute;o B & iacute;o region in Chile. Biomass samples were subjected to microwave pretreatment considering power (259, 462, 595, and 700 W) and time (1, 2, 3, and 5 min). The maximum temperature reached was 147.69 degrees C for PR and 130.71 degrees C for EG in the 700 W-5 min condition, which caused the rearrangement of the cellulose crystalline chains through vibration and an increase in the internal energy of the biomass and the decomposition of lignin due to reaching its glass transition temperature. Thermogravimetric analysis revealed an activation energy (E-a) reduction from 201.71 to 174.91 kJ center dot mol(-1) in PR and from 174.80 to 158.51 kJ center dot mol(-1) in EG, compared to the untreated condition (WOT) for the 700 W-5 min condition, which indicates that microwave pretreatment improves the activity of the components and the decomposition of structural compounds for subsequent pyrolysis. Functional groups were identified by Fourier transform infrared spectroscopy (FTIR). A decrease in oxygenated compounds such as acids (from 21.97 to 17.34% w center dot w(-1) and from 27.72 to 24.13% w center dot w(-1)) and phenols (from 34.41 to 31.95% w center dot w(-1) and from 21.73 to 20.24% w center dot w(-1)) in PR and EG, respectively, was observed in comparison to the WOT for the 700 W-5 min condition, after analytical pyrolysis. Such results demonstrate the positive influence of the pretreatment on the reduction in oxygenated compounds obtained from biomass pyrolysis.

Automated summary

The pyrolysis behavior of Pinus radiata and Eucalyptus globulus from Chile was improved through microwave pretreatment. The treatment rearranged the cellulose crystalline chains and caused lignin decomposition, resulting in enhanced activity of the components and decomposition of structural compounds.