Date of Award
12-2010
Document Type
Thesis
Degree Name
Master of Science (MS)
Legacy Department
Environmental Engineering and Science
Committee Chair/Advisor
Miller, Shelie A.
Committee Member
Lee , Cindy M.
Committee Member
Moysey , Stephen M.
Abstract
This study tries to resolve the competition between food and biofuel by balancing the allocation between food and feed areas and biofuel areas for the entire world. The maximum energy production is calculated by determining the theoretical amount of energy that can be grown, once food and feed consumption is taken into account, based on the assumption that unprotected grass and woody lands and forest lands can be converted into cultivated lands. The total optimum land area for biofuel energy, 4,926.49 Mha, consists of corn, rapeseed, sugar beet, sugar cane, and grasses. When considering energy conversion efficiency, the maximum energy production is 520.5 EJ. Of this amount, 5.9 EJ can be identified with food and feed energy and 514.6 EJ can be identified with biofuel energy. This result is a theoretical value to illustrate the potential global land area for biofuel. The biofuel energy production per area of land in this study is calculated to be 0.12 EJ/Mha. With regards to the limitation in the degree of invasion by grass and woody land and forest land areas, if it is not more than 10 percent, the biofuel energy production can serve about 76 percent of energy demand for transportation in 2009. The total optimum land area is about 45 percent of global cultivated land area. Sensitivity analysis shows that the land area of corn, sweet sorghum, sugarcane, grass, and woody crops is sensitive to energy content. The land area of sweet sorghum and soybeans is sensitive to the land area for food and feed consumption. Also, the land area of corn, sugar beet, and sugarcane is sensitive to the potential crop land area. This study, done at the global level, can also apply in a local area by using local constraints.
Recommended Citation
Pumkaew, Watcharapol, "DETERMINING THE GLOBAL MAXIMUM BIOFUEL PRODUCTION POTENTIAL WITHOUT CONFLICTING WITH FOOD AND FEED CONSUMPTION" (2010). All Theses. 1044.
https://tigerprints.clemson.edu/all_theses/1044