Sustainable biofuels set for take-off Wood contains materials which could represent a valuable resource for the gasoline and aviation fuel markets. Researchers and companies involved in the REWOFUEL project are developing sustainable methods of producing gasoline and aviation fuel from residual wood, while also making use of other co-products, as Dr Tino Lassmann explains. The aviation sector
uses large quantities of fuel, but with environmental and sustainability concerns growing, the search is on for alternatives to conventional fossil fuels. Based at the green chemicals company Sekab, Dr Tino Lassmann is part of the REWOFUEL project, an initiative working to transform residual wood into biofuels. “The process is divided into several steps before you eventually produce the aviation fuel,” he says. While the REWOFUEL project covers the entire value chain, including all the steps involved in the conversion process, Dr Lassmann’s main area of expertise is in converting the biomass into intermediate products. “At Sekab we have the skills and knowledge to open the structure of the biomass, and make the cellulose and hemicellulose accessible for conversion into sugars. These sugars are then further converted, in two separate steps, into aviation fuel,” he explains. “Our expertise lies in using biomass residues, and making the sugars that are in the biomass available, so they can then be further used for different applications.”
Pre-treating wood This involves pre-treating soft wood in order to access certain materials within it, in particular lignin, cellulose and hemicellulose.
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Lignin itself has a highly polymeric structure and a high energy content, so historically it has often been burnt, yet in recent years researchers have explored other possible applications. “It can be used in composite materials for example. In REWOFUEL we have tested lignin with a view to using it as a replacement for bitumen in asphalt. The company responsible for this was PEAB Asphalt, a Swedish road builder,” outlines Dr Lassmann. However, the main target in terms of making sugars available is cellulose, which is tightly bound in together with the lignin and the hemicellulose in woody materials such as sawdust, making it difficult to extract. “We’re using a pre-treatment process called the steam explosion process. The aim is to hydrolyse the
hemi-cellulose in woody material, which then makes the cellulose accessible for the next step, the so-called enzymatic hydrolysis,” continues Dr Lassmann. The steam explosion process takes place in a high-pressure reactor, with different catalysts available to solubilize the hemicellulose in the sawdust. Due to the pressure drop at the outlet of the reactor the structure is opened – the ‘explosion’ – and its surface area increases, which then makes it easier for the enzymes to go in and do their job. “The enzymes are then responsible for the conversion of cellulose which is a long-chain sugar - into short-chain sugars, by cutting them at the right position,” explains Dr Lassmann. The steam explosion process is one of Sekab’s core technologies, with technology experts able to modify how it is run so as to maximise the amount of cellulose that is subsequently made available for enzymatic hydrolysis, while Dr Lassmann says there are also other factors to consider. “It’s also important to minimise the amount of acids or inhibitors that are produced during the pre-treatment process, as they can limit the effectiveness of the enzymatic hydrolysis,” he outlines. By modifying the operational conditions of the reactor, in particular the temperature, pressure and residence time, Dr Lassmann and his colleagues are able to influence the
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