Analytical Approaches to Understanding the Role of Non-carbohydrate Components in Wood Biorefinery

This dissertation describes the production and analysis of wood subjected to a novel electron beam-steam explosion pretreatment (EB-SE) pretreatment with the aim to evaluate its suitability for the production of bioethanol. The goal of these studies was to: 1) develop analytical methods for the investigation of depolymerization of wood components under pretreatments, 2) analyze the effects of EB-SE pretreatment on the pretreated biomass, 3) define how lignin and extractive components affect the action of enzymes on cellulosic substrates, and 4) examine how changes in lignin structure impact its isolation and potential conversion into value added chemicals.;The first section of the work describes the development of a size-exclusion chromatography (SEC) methodology for molecular weight analysis for native and pretreated wood. The selective analysis of carbohydrates and lignin from native wood was made possible by the combination of two selective derivatization methods, ionic liquid assisted benzoylation of the carbohydrate fraction and acetobromination of the lignin in acetic acid media. This method was then used to examine changes in softwood samples after the EB-SE pretreatment. The methodology was shown to be effective for monitoring changes in the molecular weight profiles of the pretreated wood.;The second section of the work investigates synergistic effects of the EB-SE pretreatment on the molecular level structures of wood components and the significance of these alterations in terms of enzymatic digestibility. The two pretreatment steps depolymerized cell wall components in different fashion, while showing synergistic effects. Hardwood and softwood species responded differently to similar treatment conditions, which was attributed to the well-known differences in the structure of their lignin and hemicellulose fractions. The relatively crosslinked lignin in softwood appeared to limit swelling and subsequent depolymerization in comparison to hardwood. Additional studies revealed that an insoluble, likely crosslinked, lignin fraction induced enzyme inhibition, while soluble lower molecular weight fractions were slightly beneficial for the enzymatic hydrolysis of cellulose.;The third section of the work addresses the influence of hydrophobic wood extractives and representative model compounds on the cellulolytic hydrolysis of cellulosic substrates. Deposition of specific fractions of isolated wood extractives on cellulose was found either to enhance or inhibit the action of cellulase enzymes, depending on the chemical nature of the fraction. Using model compounds this effect was found to be correlated with the compounds chemical structure, and underlying mechanisms could be rationalized by Hansen solubility parameter considerations. The amphiphilic and hydrophobic nature of the model extractives was found to influence the deposition of extractives on the cellulose surfaces, and the adsorption of cellulolytic enzymes, as measured with Quartz Crystal Microgravimetry. Beneficial effects of the extractives were likely related to reduction in the irreversible binding of the enzymes on the cellulose substrate.;The fourth section of the work deals with the recovery of lignin using extraction methods based on aqueous alkali or aqueous ethanol. The objective of this study was to understand how the yield, MW and structure of lignin recovered from the process residue was impacted by the different isolation methods. Mild extraction conditions allowed for recovery of approximately 40 wt.% of the lignin present in the process residues. Base or acid catalyzed hydrolysis of the lignin could increase the recovery lignin yield to about 76 wt.%. The recovered lignins were characterized in terms of their functional groups, molecular weights and thermal properties. The lignins from mild alkali and ethanol extractions showed similarities in their chemical profiles while, as expected, the hydrolyzed lignins were different and depended on the hydrolysis conditions. The molecular weight and thermal properties of the lignin products were affected by the applied isolation process.