Abstract
The pretreatment of lignocellulosic materials to obtain cellulose generates a residual stream with hemicellulosic composition, mainly containing xylose. This C5 fraction is not directly fermentable by microorganisms traditionally used to produce ethanol. Hence, more promising alternatives for the C5 fraction have been studied, and acidogenic fermentation proves to be an attractive option for the production of biohydrogen, due to the possibility of using hemicellulose fractions and mixed anaerobic cultures. To reduce the activity of hydrogen-consuming microorganisms when mixed cultures are employed as inoculum to produce hydrogen by anaerobic fermentation, thermal pretreatment was selected. However, such pretreatment method also affects the activity of hydrogen-producing acidogenic bacteria, and strategies should be studied to enrich the inoculum for these bacteria and to increase hydrogen yields. Thus, this study evaluated the effect of some strategies on the biohydrogen production from xylose. The strategies adopted were thermal pretreatment of the sludge, maintenance of the incubation temperature at 35 °C, adaptation of the sludge by successive contacts with the xylose solution, and increasing inoculum to substrate ratio (I/S) from 1 to 2. This approach improved hydrogen yield approximately 30 times, from 0.03 to 0.93 mmol H2/mmol xylose. However, this yield was only 56% of the theoretical value and can still be improved.
Highlights
The constant demand for energy and the unsustainable use of fossil fuels with their environmental problems have influenced the need to explore sustainable resources, clean sources, and lower costs
The chemical composition (Table 1) of hemicellulose fraction obtained from sugarcane straw is mostly pentoses sugars, with xylose the main component (60% of the total composition)
Both pentose and hexose sugars present in the studied hydrolyzate are a rich source of organic matter and can be assimilated by the acidogenic bacteria to produce H2, CO2, and various metabolites
Summary
The constant demand for energy and the unsustainable use of fossil fuels with their environmental problems have influenced the need to explore sustainable resources, clean sources, and lower costs. From the environmental point of view, the challenge of using hydrogen as an energy vector lies in its sustainable production, which becomes attractive when combined with low-energy biological processes and the use of agricultural (Ghimire et al, 2015) and agro-industrial wastes (Urbaniec & Bakker, 2015). These materials have been widely studied as raw materials with high energy potential and value added, due to their abundance and low or no cost, contributing to waste management (Ratti, Delforno, Sakamoto, & Varesche, 2015). The pretreatment of lignocellulosic materials to obtain cellulose generates a residual material with hemicellulosic composition (Sarkar, Ghosh, Bannerjee, & Aikat, 2012)
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