265885 Genetically Modified Biomass: Effect of Single Gene Modifications On the Composition of Fast Pyrolysis Bio-Oils

Tuesday, October 30, 2012: 8:50 AM
303 (Convention Center )
Kevin M. Van Geem1, Yumi Van Wonterghem2, Eleonora Boren3,4, Ruben Vanholme3,4, Lorenz Gerber5, Marko Djokic2, Frederick Ronsse2, Wolter Prins2, Bj÷rn Sundberg5, Wout Boerjan3,4 and Guy Marin6, (1)Department of Chemical technology, Ghent University, Ghent, Belgium, (2)UGent, (3)Department of Plant Biotechnology and Bioinformatics, Ghent University, Ghent, Belgium, (4)Department of Plant Systems Biology, VIB, Ghent, Belgium, (5)Forest Genetics and Plant Physiology, Swedish University of Agricultural Sciences, Umeň, Sweden, (6)Ghent university, Ghent, Belgium

It has been premised that lignocellulosic biomass is theá main renewable energy resourcesá available here on earth and con be considered as one of few sources that can provide renewable liquid, gaseous and solid fuels. In contrast to fossil fuels, the use of biomass for energy renders significant environmental advantages. Plant growth needed to generate biomass feedstocks removes atmospheric carbon dioxide, which offsets the increase in atmospheric carbon dioxide that results from biomass fuel combustion.

One promising and clean way to acquire bio-oil is by the fast pyrolysis of biomass, which is considered as a network of rich hemicellulose and cellulose bound by lignin. This process is carried out in the absence of oxygen, or when significantly less oxygen is present than required for complete combustion, and at elevated temperatures, thus yielding in gaseous products, liquids (bio-oil and water) and solid charcoal. The bio-oil contains a broad range of organic chemicals; hence they offer the potential to be used as an energy carrier, or as a renewable raw material for the chemical industry for the production of high-value chemicals and liquid biofuels. The valorization of the phenolics as building blocks or new synthetic bioplastics, phenol-formaldehyde resins or epoxy- or polyurethane materials,.. are some of the many possible applications. Another possibility is to use the bio-oil as a refinery feedstock for the production of the much needed biofuels. This requires upgrading via hydrodeoxygenation (HDO) with hydrogen over CoMo or NiMo catalysts, which nevertheless imposes some other challenges that need to be overcome.

However, realizing those potential applications requires having the control over the chemical composition of the bio-oil. Thus the right type of biomass and the pyrolysis conditions should be selected. In short, to understand and to be able to predict the pyrolysis behavior, it is essential to understand the kinetics of the thermal reactions that are involved in the decomposition of biomass. Up to now, the goal of the fast pyrolysis process was limited to convert as much biomass as possible to liquid bio-oil, neglecting the effect(s) of the biomass composition and/or the process conditions on the bio-oil composition. Therefore in this presentation the role of feed and process conditions is extensively investigated on the bio-oil composition. Both pyrolysis GC as well as pilot plant data will be discussed of more than 20 different genetically modified biomass feeds. Single gene modifications of Arabidopsis and poplar have been evaluated and the effect of these modifications on the biomass composition and produced bio-oil has been evaluated. This requires a comprehensive set of analytical techniques such as comprehensive 2D GC and LC to unravel the complexity of both feed and product. á

 


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