Influence of proteins on the hydrothermal gasification and liquefaction of biomass. 2. Model compounds

The hydrothermal gasification is a promising process to produce hydrogen from biomass with high water content. In a lot of cases, this biomass may contain proteins, for example, in residues from the food industry or sewage sludge. In Part I of this serial, experiments on hydrothermal gasification of protein containing biomass (zoo mass) have been reported. This biomass produces lower gas yields than biomass originating exclusively from plants (phyto mass). To understand these findings, experiments with model compounds are necessary. Here, such experiments with model compounds in a tubular and a batch reactor are described. The model system for the phyto mass is glucose with a potassium salt, and the model system for the zoo mass is glucose, potassium salt, and the amino acid alanine. The model systems show a lower gas yield in the presence of alanine. So the presence of alanine in the model system has a similar effect to the presence of proteins in biomass. Additionally, the gas composition and the concentration of selected key compounds are slightly changed by alanine addition. Likely, consecutive products of carbohydrate and protein degradation react with each other. In such Maillard reactions, free radical scavengers might be formed, reducing the reaction rate of free radical chain reactions that are highly relevant for gas formation. Therefore, the gas yield is lower in the presence of proteins or amino acids compared with systems without these compounds. In addition, experiments with real biomass in a batch reactor were reported to verify the assumption of Maillard products reducing free radical reactions. As an example, the addition of urea to phyto mass leads to a decrease of the gas yield to a value similar to that found for zoo mass.