Biomass supply and nutrient runoff abatement under alternative biofuel feedstock production subsidies

The objective of this paper is to design two types of subsidies for biofuel feedstock production and water quality improvement and to analyze how each subsidy affects biomass supply and the abatement of nutrient runoff associated with the conversion of cropland to biomass production. Per-hectare (pe...

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Bibliographic Details
Published in:Agricultural systems 2015-10, Vol.139, p.250-259
Main Authors: Zhou, Xia “Vivian”, Clark, Christopher D., Lambert, Dayton M., English, Burton C., Larson, James A., Boyer, Christopher N.
Format: Article
Language:English
Subjects:
Abatement of nutrient runoff
Biofuel feedstock production
Dynamic programming
Per-hectare (per-ha) subsidy
Per-megagram (per-Mg) subsidy
Switchgrass
Water quality improvement
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Summary:The objective of this paper is to design two types of subsidies for biofuel feedstock production and water quality improvement and to analyze how each subsidy affects biomass supply and the abatement of nutrient runoff associated with the conversion of cropland to biomass production. Per-hectare (per-ha) subsidy was designed as a system that pays producers for each ha of cropland converted to switchgrass production and per-megagram (per-Mg) subsidy was a system that pays producers for each Mg of switchgrass produced. This study focuses on Oostanaula Creek watershed in East Tennessee. The analysis used a dynamic programming model coupled with a Soil and Water Assessment Tool (SWAT) simulation model to predict profit-maximizing fertilizer application rates, crop yields, and nitrogen (N) runoff for a biofuel feedstock (switchgrass) and a conventional crop (corn) across 28 different landscapes in the watershed. A Monte Carlo analysis was conducted to simulate the impact of stochastic N fertilizer and corn prices and yields on subsidies over a ten-year planning horizon. A per-ha subsidy system is more cost effective and feasible than a per-Mg system because the former has significantly lower subsidy than the latter for each kilogram (kg) of N reduction and for each Mg of switchgrass harvested. Converting all of the cropland from corn to switchgrass over ten years results in 124,084 dry Mg of switchgrass and 23% reduction in nitrogen runoff for the per-ha system and 122,347 dry Mg of switchgrass and 3% reduction for the per-Mg subsidy system. •Per-Mg and per-ha subsidies were designed for biomass production and water quality improvement.•A dynamic programming model was developed to profit-maximize fertilizer application.•Per-ha subsidy was more cost effective than per-Mg for biomass supply and nutrient runoff reduction.•For per-ha system, 10-yr switchgrass production vs corn results in 23% reduction in nitrogen runoff•For per-Mg system, 10-yr switchgrass production vs corn results in 3% reduction in nitrogen runoff
ISSN:0308-521X
1873-2267
DOI:10.1016/j.agsy.2015.08.002