Analysis of component interaction in beech wood pyrolysis by native mixing with mildly invasive pretreatments
Carmen Branca, Colomba Di Blasi
Abstract
Component interactions in biomass pyrolysis are often investigated through native mixtures obtained by partially destructive chemical pretreatments. In this study, mild pretreatments (washing and washing-torrefaction) are applied to beech wood. They are apt to preserve the main chemical structure of the constituents and the role of their mutual bonds in pyrolysis and to reduce or eliminate the overlap between hemicellulose and cellulose decomposition. Then, exploiting recently available lignin data and model fitting, decomposition kinetics of natural cellulose and hemicellulose is clearly identified and determined. The activation energies (157 and 170 kJ/mol) for the two hemicellulose reactions are not affected by pretreatments. Moreover, that for the single stage of cellulose decomposition is weakly modified (from 200 to 222 kJ/mol) only by washing. The interactions and the possible synergies among components always give rise to char yields lower (factors around 2–3) than those observed from model compounds or chemically isolated ones and remarkable different conversion dynamics. These findings indicate that mixing approaches, not fully incorporating component interactions, are not quantitatively accurate. Primary decomposition mechanisms of more general validity, accounting for quantities, properties and mutual interactions of natural components, are also the first requirement for accurate modeling of secondary reaction processes within the complex microporous structure of wood. • A method is proposed to investigate in-situ decomposition of wood components. • Mildly invasive pretreatments separate hemicellulose from cellulose decomposition. • Decomposition of natural carbohydrates differs from model or isolated compounds. • Component interaction gives rise to modified thermal stability and lower char yields. • Natural components substitute pseudo-components in a new wood pyrolysis mechanism.