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1 Department of Environmental Engineering, Technical University of Denmark 2 Residual Resource Engineering, Department of Environmental Engineering, Technical University of Denmark 3 University of Southern Denmark
In the endeavor of optimizing the sustainability of bioenergy production in Denmark, this consequential life cycle assessment (LCA) evaluated the environmental impacts associated with the production of heat and electricity from one hectare of Danish arable land cultivated with three perennial crops: ryegrass (Lolium perenne), willow (Salix viminalis) and Miscanthus giganteus. For each, four conversion pathways were assessed against a fossil fuel reference: (I) anaerobic co-digestion with manure, (II) gasification, (III) combustion in small-to-medium scale biomass combined heat and power (CHP) plants and IV) co-firing in large scale coal-fired CHP plants. Soil carbon changes, direct and indirect land use changes as well as uncertainty analysis (sensitivity, MonteCarlo) were included in the LCA. Results showed that global warming was the bottleneck impact, where only two scenarios, namely willow and Miscanthus co-firing, allowed for an improvement as compared with the reference (-82 and -45 t CO2-eq. ha-1, respectively). The indirect land use changes impact was quantified as 310 ± 170 t CO2-eq. ha-1, representing a paramount average of 41% of the induced greenhouse gas emissions. The uncertainty analysis confirmed the results robustness and highlighted the indirect land use changes uncertainty as the only uncertainty that can significantly change the outcome of the LCA results. © 2012 American Chemical Society.
Environmental Science and Technology (washington), 2012, Vol 46, Issue 24, p. 13521-13530
Anaerobic digestion; Carbon dioxide; Coal combustion; Coal gasification plants; Cogeneration plants; Crops; Environmental impact; Fossil fuels; Gas emissions; Global warming; Greenhouse gases; Land use; Manures; Power generation; Uncertainty analysis; Life cycle
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