The Effect of Changing Ethanol Production on the Harvested Area and CO2 Emissions

Volume 1, Issue 2, December 2016     |     PP. 71-81      |     PDF (516 K)    |     Pub. Date: December 26, 2016
DOI:    329 Downloads     8182 Views  

Author(s)

Mahmoud Salari, Department of Economics, Texas Tech University, Lubbock, TX 79409-1014, United States
Roxana J. Javid, Department of Engineering Technology, Savannah State University, Savannah, GA 31404-5254, United States

Abstract
In the last decade biofuel production has been increasing dramatically. Recently several countries have introduced mandates and targets for biofuel expansion. This paper revisits the recent developments in biofuel production and its impact on the harvested area and CO2 emissions for producers and rest of the world. Three defined scenarios suggested in this paper. Scenario I, scenario II and scenario III show 50%, 100% and 150% increasing ethanol production respectively in the world. Our results show that the impact of increasing production of ethanol has different impact for producers and rest of the world. Our different scenarios indicate that the increasing 50% ethanol production wouldn’t result the same portion increasing in the amount of harvested area. Moreover, Increasing of ethanol production have significant impact on the CO2 emissions for producers countries and whole world. We have experienced decreasing CO2 emissions in the producers’ countries and increasing CO2 emission in the rest of the world.

Keywords
Ethanol production, Global trade analysis project, Harvested area, CO2 emissions

Cite this paper
Mahmoud Salari, Roxana J. Javid, The Effect of Changing Ethanol Production on the Harvested Area and CO2 Emissions , SCIREA Journal of Energy. Volume 1, Issue 2, December 2016 | PP. 71-81.

References

[ 1 ] Koh MY, Mohd. Ghazi TI. A review of biodiesel production from Jatropha curcas L. oil. Renewable and Sustainable Energy Reviews 2011;15:2240–51.
[ 2 ] Javid RJ, Nejat A, Hayhoe K. Selection of CO2 mitigation strategies for road transportation in the United States using a multi-criteria approach. Renewable and Sustainable Energy Reviews 2014;38:960–72.
[ 3 ] Salari M, Javid RJ. Residential energy demand in the United States : Analysis using static and dynamic approaches. Energy Policy 2016;98:637–49.
[ 4 ] Javid RJ. P16-Greenhouse gas and air pollution emission reduction from incentivized carpooling. Journal of Transport & Health 2016;3:S71.
[ 5 ] Javid RJ, Nejat A. A comprehensive model of regional electric vehicle adoption and penetration. Transport Policy 2017:(forthcoming).
[ 6 ] Javid RJ, Nejat A, Hayhoe K. Quantifying the environmental impacts of carpooling on HOV lanes in the United States. Transportation Research Part D: Transport and Environment 2017:(forthcoming).
[ 7 ] Javid RJ. Online estimation of travel time variability using the integrated traffic incident and weather data. Transportation Research Board 96th Annual Meeting, Washington, DC 2017:(forthcoming).
[ 8 ] Javid RJ, Nejat A, Salari M. The environmental impacts of carpooling in the United States 2016.
[ 9 ] Hamilton IG, Steadman PJ, Bruhns H, Summerfield AJ, Lowe R. Energy efficiency in the British housing stock: Energy demand and the homes energy efficiency database. Energy Policy 2013;60:462–80.
[ 10 ] Alberini A, Gans W, Velez-Lopez D. Residential consumption of gas and electricity in the U.S. : The role of prices and income. Energy Economics 2011;33:870–81.
[ 11 ] López-rodríguez MA, Santiago I, Trillo-montero D, Torriti J, Moreno-munoz A. Analysis and modeling of active occupancy of the residential sector in Spain : An indicator of residential electricity consumption. Energy Policy 2013;62:742–51.
[ 12 ] Ueno T, Sano F, Saeki O, Tsuji K. Effectiveness of an energy-consumption information system on energy savings in residential houses based on monitored data. Applied Energy 2006;83:166–83.
[ 13 ] Salari M, Javid RJ. Modeling household energy expenditure in the United States. Renewable and Sustainable Energy Reviews 2017:(forthcoming).
[ 14 ] Naik SN, Goud V V., Rout PK, Dalai AK. Production of first and second generation biofuels: A comprehensive review. Renewable and Sustainable Energy Reviews 2010;14:578–97.
[ 15 ] Ravindranath NH, Sita Lakshmi C, Manuvie R, Balachandra P. Biofuel production and implications for land use, food production and environment in India. Energy Policy 2011;39:5737–45.
[ 16 ] Mussatto SI, Dragone G, Guimarães PMR, Silva JP a, Carneiro LM, Roberto IC, et al. Technological trends, global market, and challenges of bio-ethanol production. Biotechnology Advances 2010;28:817–30.
[ 17 ] Field CB, Campbell JE, Lobell DB. Biomass energy : the scale of the potential resource. Trends in Ecology & Evolution 2008;23:65–72.
[ 18 ] Cai X, Zhang X, Wang D. Land availability for biofuel production. Environmental Science & Technology 2011;45:334–9.
[ 19 ] Kim S, Dale BE, Ong RG. An alternative approach to indirect land use change: Allocating greenhouse gas effects among different uses of land. Biomass and Bioenergy 2012;46:447–52.
[ 20 ] Lapola DM, Schaldach R, Alcamo J, Bondeau A, Koch J, Koelking C, et al. Indirect land-use changes can overcome carbon savings from biofuels in Brazil. Proceedings of the National Academy of Sciences of the United States of America 2010;107:3388–93.
[ 21 ] Banse M, van Meijl H, Tabeau A, Woltjer G, Hellmann F, Verburg PH. Impact of EU biofuel policies on world agricultural production and land use. Biomass and Bioenergy 2011;35:2385–90.
[ 22 ] Sorda G, Banse M, Kemfert C. An overview of biofuel policies across the world. Energy Policy 2010;38:6977–88.
[ 23 ] Truong TP. Model with Emission Trading USER ’ S GUIDE The GTAP-E Modules 2007.
[ 24 ] Burniaux J-M, Truong T. GTAP-E : An Energy-Environmental Version of the GTAP Model. GTAP Technical Paper No 16 2002.
[ 25 ] Birur D, T. H, W. T. Impact of biofuel production on world agriculture markets : A computable general equilibrium analysis. GTAP Working Paper 53 Center for Global Trade Analysis, Prdue University 2008.
[ 26 ] Carriquiry M a., Du X, Timilsina GR. Second generation biofuels : Economics and policies. Energy Policy 2011;39:4222–34.
[ 27 ] Bondesson P-M, Galbe M, Zacchi G. Ethanol and biogas production after steam pretreatment of corn stover with or without the addition of sulphuric acid. Biotechnology for Biofuels 2013;6:11.
[ 28 ] Grafton RQ, Kompas T, Long N Van, To H. US biofuels subsidies and CO2 emissions: An empirical test for a weak and a strong green paradox. Energy Policy 2014;68:550–5.