124 used as the sole fuel source in cogeneration plants (e.g., electricity, low-pressure steam production) and for heat/power generation by co-firing with coal or other fossil fuel sources. Conversion to sustainable options such as linking biomass generation of methanol to H has the potential to reduce GHG emissions by 80-90% over current practices (Makinen and Sipilá 2003). Emerging Opportunities in Linking Biomass Conversions to Hydrogen Fuel Cell Systems The practice of using biomass to produce methanol has only recently been suggested as a fuel source for hydrogen fuel cells (Sigurdardottir et. al. 2003, Vogt et al. 2004). Sigurdardottir et. al. (2003) and Vogt et. al. (2004) proposed a system which potentially can increase the use of biomass as a renewable resource in decentralized energy production systems that generate electricity using H fuels cells (see figure 1). Methanol is the key liquid fuel driving rapid developments in fuel cell technology (Methanex 2003, IdaTech 2003, The Economist 23/10/97 & 22/04/99). While traditionally methanol is mostly produced from natural gas, a non-renewable resource (Kheshgi et al. 2000), wood based processes being developed today are becoming more sophisticated and efficient, for example, flash pyrolysis and hydrothermal liquefaction (Bridgewater 1999, TNO 2003). As recent as the 1990s, methanol production from wood was considered economically not viable since it was less expensive to produce it from natural gas (Sedjo 1997, Ohlström et al. 2001). Several factors are changing the economic accounting scenarios of the past: inclusion of environment sustainability and security factors as part of cost/benefit analyses, tax incentives/carbon tax on energy production (implemented in Sweden, Austria, others), regulations mandating the increase in the proportion of energy consumed from renewable resources to mitigate GHG emissions (CEC 1997, FAO 2002). Using forests or agricultural resources and wastes to generate altemative energy is optimal, as renewable resources are being used, and biomass conversions can be made using environmentally sound chemical practices. These practices can also provide environmental services such as maintaining forest nutrient status by reapplying the residues from biomass conversion processes on the site (Andersson and Emilsson 2003). Mákinen and Sipilá (2003) suggested ethanol and biodiesel are short-term solutions for acquiring biofuels and that the most significant GHG emission reductions will likely come from using methanol and hydrogen fuel cell systems. Wood has a more consistent chemical composition, it a more efficient and reliable starting material to produce methanol (Brown 2003). Wood can be used as a starting material to produce methanol using one of two main processes: 1) gasification, and 2) pyrolysis. In the past 10 years, much engineering research and development are allowing the commercialization of biomass conversion systems. In particular, European countries, such as The Netherlands, Finland, Sweden, and Germany, have been very active in this area. While not yet perfected, gasification or pyrolysis of biomass efficiently produces a liquid fuel such as methanol. A system for transforming forest biomass to methanol on a small scale has not been commercialized to date, but is a logical goal since wood is a higher quality, starting material with a more consistent chemical composition than many other types of biomass. These qualities make wood a more reliable material to transform to methanol. The efficiency of chemical conversion and the resulting products will vary

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