2009
DOI: 10.1111/j.1530-9290.2008.00105.x
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Improvements in Life Cycle Energy Efficiency and Greenhouse Gas Emissions of Corn‐Ethanol

Abstract: SummaryCorn-ethanol production is expanding rapidly with the adoption of improved technologies to increase energy efficiency and profitability in crop production, ethanol conversion, and coproduct use. Life cycle assessment can evaluate the impact of these changes on environmental performance metrics. To this end, we analyzed the life cycles of corn-ethanol systems accounting for the majority of U.S. capacity to estimate greenhouse gas (GHG) emissions and energy efficiencies on the basis of updated values for … Show more

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Cited by 254 publications
(225 citation statements)
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References 17 publications
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“…However, using the ICI and CCI we observe that by 2040 the climate impact of algae biodiesel surpasses that of corn ethanol, owing to CH 4 leakage in biogas production from algae co-products, which partially offsets the energy requirements of algae production and processing [2]. Although these offsets make biodigestors attractive, with applications in corn ethanol production [25] and other biofuels, resulting CH 4 emissions may make this process less advantageous over time. An alternative catalytic hydrothermal gasification process may achieve much lower CH 4 emissions (Supplementary Fig.…”
Section: Gasoline"mentioning
confidence: 96%
“…However, using the ICI and CCI we observe that by 2040 the climate impact of algae biodiesel surpasses that of corn ethanol, owing to CH 4 leakage in biogas production from algae co-products, which partially offsets the energy requirements of algae production and processing [2]. Although these offsets make biodigestors attractive, with applications in corn ethanol production [25] and other biofuels, resulting CH 4 emissions may make this process less advantageous over time. An alternative catalytic hydrothermal gasification process may achieve much lower CH 4 emissions (Supplementary Fig.…”
Section: Gasoline"mentioning
confidence: 96%
“…Hill et al (2006) show that among current food-based biofuels, soybean biodiesel has much higher GHG reduction potential than corn grain ethanol. However, Liska et al (2009) argue that the GHG reduction potential of corn could be significantly improved to the levels of sugar beets or soybeans through enhanced yield and crop management, biorefinery operation, and co-product utilization. Cui et al (2010) construct an open economy general equilibrium model to investigate the effects of government energy policy on the US economy, with an emphasis on the corn-based ethanol.…”
Section: Environmental Impactsmentioning
confidence: 99%
“…Biorefinery scenarios evaluated in this study are: (i) a natural gas (NG) dry mill corn grain ethanol plant with dry distillers grain (DDGS) as a co-product for the corn grain-only harvests [23][24][25], (ii) a co-located dry mill corn grain and cellulosic ethanol plant with combined heat and power (CHP) and DDGS co-product, where corn stover is primarily used to displace dry mill ethanol plant natural gas requirements [25,26], (iii) and a standalone cellulosic (switchgrass or corn stover) ethanol plant (sequential hydrolysis and fermentation) with CHP capability and electricity export [22, [27][28][29]. Chemical and enzyme production costs and related GHG emissions for corn grain and cellulosic conversion to ethanol were also incorporated [28].…”
Section: Life-cycle Assessmentmentioning
confidence: 99%