1. High-resolution techno–ecological modelling of a bioenergy landscape to identify climate mitigation opportunities in cellulosic ethanol production
- Author
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Ernie Marx, Samuel G. Evans, Mark Easter, Thai Dinh, Paul R. Adler, Keith Paustian, John L. Field, and Bryan Willson
- Subjects
Renewable Energy, Sustainability and the Environment ,020209 energy ,Renewable Fuel Standard ,Energy Engineering and Power Technology ,Biomass ,02 engineering and technology ,Electronic, Optical and Magnetic Materials ,Energy crop ,Fuel Technology ,Cellulosic ethanol ,Biofuel ,Bioenergy ,Environmental protection ,Greenhouse gas ,0202 electrical engineering, electronic engineering, information engineering ,Environmental science ,GHG footprint - Abstract
Although dedicated energy crops will probably be an important feedstock for future cellulosic bioenergy production, it is unknown how they can best be integrated into existing agricultural systems. Here we use the DayCent ecosystem model to simulate various scenarios for growing switchgrass in the heterogeneous landscape that surrounds a commercial-scale cellulosic ethanol biorefinery in southwestern Kansas, and quantify the associated fuel production costs and lifecycle greenhouse gas (GHG) emissions. We show that the GHG footprint of ethanol production can be reduced by up to 22 g of CO2 equivalent per megajoule (CO2e MJ–1) through careful optimization of the soils cultivated and corresponding fertilizer application rates (the US Renewable Fuel Standard requires a 56 gCO2e MJ−1 lifecycle emissions reduction for ‘cellulosic’ biofuels compared with conventional gasoline). This improved climate performance is realizable at modest additional costs, less than the current value of low-carbon fuel incentives. We also demonstrate that existing subsidized switchgrass plantings within this landscape probably achieve suboptimal GHG mitigation, as would landscape designs that strictly minimize the biomass collection radius or target certain marginal lands. Dedicated energy crops are an important feedstock for bioenergy systems, but uncertainties remain over how best to integrate them into agricultural landscapes. Here, the authors use high-resolution ecosystem modelling to explore how selection of the soils cultivated and fertilizer application rates affects feedstock costs and emissions footprints.
- Published
- 2018
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