“Ethanol fuel”的意思、由来-开放百科全书

Ethanol fuel has a "gasoline gallon equivalency" (GGE) value of 1.5, i.e. to replace the energy of 1 volume of gasoline, 1.5 times the volume of ethanol is needed.^[3]^[4]

Ethanol-blended fuel is widely used in Brazil, the United States, and Europe (see also Ethanol fuel by country).^[2] Most cars on the road today in the U.S. can run on blends of up to 10% ethanol,^[5] and ethanol represented 10% of the U.S. gasoline fuel supply derived from domestic sources in 2011.^[2] Furthermore, many used cars today are flexible-fuel vehicles able to use 100% ethanol fuel.

Since 1976 the Brazilian government has made it mandatory to blend ethanol with gasoline, and since 2007 the legal blend is around 25% ethanol and 75% gasoline (E25).^[6] By December 2011 Brazil had a fleet of 14.8 million flex-fuel automobiles and light trucks^[7]^[8] and 1.5 million flex-fuel motorcycles^[9]^[10]^[11] that regularly use neat ethanol fuel (known as E100).

Bioethanol is a form of renewable energy that can be produced from agricultural feedstocks. It can be made from very common crops such as hemp, sugarcane, potato, cassava and corn. There has been considerable debate about how useful bioethanol is in replacing gasoline. Concerns about its production and use relate to increased food prices due to the large amount of arable land required for crops,^[12] as well as the energy and pollution balance of the whole cycle of ethanol production, especially from corn. Even though this debate has the counterpart of animal agriculture being already a source of massive arable land, therefore making ethanol a lower resource consumer in constrast. ^[13]^[14] Recent developments with cellulosic ethanol production and commercialization may allay some of these concerns.^[15]

Chemistry

During ethanol fermentation, glucose and other sugars in the corn (or sugarcane or other crops) are converted into ethanol and carbon dioxide.

Ethanol fermentation is not 100% selective with side products such as acetic acid and glycols. They are mostly removed during ethanol purification. Fermentation takes place in an aqueous solution. The resulting solution has an ethanol content of around 15%. Ethanol is subsequently isolated and purified by a combination of adsorption and distillation.

During combustion, ethanol reacts with oxygen to produce carbon dioxide, water, and heat:

Starch and cellulose molecules are strings of glucose molecules. It is also possible to generate ethanol out of cellulosic materials. That, however, requires a pretreatment that splits the cellulose into glucose molecules and other sugars that subsequently can be fermented. The resulting product is called cellulosic ethanol, indicating its source.

Ethanol is also produced industrially from ethylene by hydration of the double bond in the presence of a catalyst and high temperature.

Sources

About 5% of the ethanol produced in the world in 2003 was actually a petroleum product.^[19] It is made by the catalytic hydration of ethylene with sulfuric acid as the catalyst. It can also be obtained via ethylene or acetylene, from calcium carbide, coal, oil gas, and other sources. {{convert|2,000,000|ST|LT t|sigfig=4|spell=In}} of petroleum-derived ethanol are produced annually. The principal suppliers are plants in the United States, Europe, and South Africa.^[20] Petroleum derived ethanol (synthetic ethanol) is chemically identical to bio-ethanol and can be differentiated only by radiocarbon dating.^[21]

Bio-ethanol is usually obtained from the conversion of carbon-based feedstock. Agricultural feedstocks are considered renewable because they get energy from the sun using photosynthesis, provided that all minerals required for growth (such as nitrogen and phosphorus) are returned to the land. Ethanol can be produced from a variety of feedstocks such as sugar cane, bagasse, miscanthus, sugar beet, sorghum, grain, switchgrass, barley, hemp, kenaf, potatoes, sweet potatoes, cassava, sunflower, fruit, molasses, corn, stover, grain, wheat, straw, cotton, other biomass, as well as many types of cellulose waste and harvesting, whichever has the best well-to-wheel assessment.

An alternative process to produce bio-ethanol from algae is being developed by the company Algenol. Rather than grow algae and then harvest and ferment it, the algae grow in sunlight and produce ethanol directly, which is removed without killing the algae. It is claimed the process can produce {{convert|6000|usgal/acre|impgal/acre L/ha|abbr=none|sp=us}} per year compared with {{convert|400|usgal/acre|impgal/acre L/ha}} for corn production.^[22]

Currently, the first generation processes for the production of ethanol from corn use only a small part of the corn plant: the corn kernels are taken from the corn plant and only the starch, which represents about 50% of the dry kernel mass, is transformed into ethanol. Two types of second generation processes are under development. The first type uses enzymes and yeast fermentation to convert the plant cellulose into ethanol while the second type uses pyrolysis to convert the whole plant to either a liquid bio-oil or a syngas. Second generation processes can also be used with plants such as grasses, wood or agricultural waste material such as straw.

Production

Although there are various ways ethanol fuel can be produced, the most common way is via fermentation.

The basic steps for large-scale production of ethanol are: microbial (yeast) fermentation of sugars, distillation, dehydration (requirements vary, see Ethanol fuel mixtures, below), and denaturing (optional). Prior to fermentation, some crops require saccharification or hydrolysis of carbohydrates such as cellulose and starch into sugars. Saccharification of cellulose is called cellulolysis (see cellulosic ethanol). Enzymes are used to convert starch into sugar.^[23]

Fermentation

Ethanol is produced by microbial fermentation of the sugar. Microbial fermentation currently only works directly with sugars. Two major components of plants, starch and cellulose, are both made of sugars—and can, in principle, be converted to sugars for fermentation. Currently, only the sugar (e.g., sugar cane) and starch (e.g., corn) portions can be economically converted. There is much activity in the area of cellulosic ethanol, where the cellulose part of a plant is broken down to sugars and subsequently converted to ethanol.

Distillation

For the ethanol to be usable as a fuel, the yeast solids and the majority of the water must be removed. After fermentation, the mash is heated so that the ethanol evaporates.^[24] This process, known as distillation, separates the ethanol, but its purity is limited to 95–96% due to the formation of a low-boiling water-ethanol azeotrope with maximum (95.6% m/m (96.5% v/v) ethanol and 4.4% m/m (3.5% v/v) water). This mixture is called hydrous ethanol and can be used as a fuel alone, but unlike anhydrous ethanol, hydrous ethanol is not miscible in all ratios with gasoline, so the water fraction is typically removed in further treatment to burn in combination with gasoline in gasoline engines.^[25]

Dehydration

There are three dehydration processes to remove the water from an azeotropic ethanol/water mixture. The first process, used in many early fuel ethanol plants, is called azeotropic distillation and consists of adding benzene or cyclohexane to the mixture. When these components are added to the mixture, it forms a heterogeneous azeotropic mixture in vapor–liquid-liquid equilibrium, which when distilled produces anhydrous ethanol in the column bottom, and a vapor mixture of water, ethanol, and cyclohexane/benzene.

When condensed, this becomes a two-phase liquid mixture. The heavier phase, poor in the entrainer (benzene or cyclohexane), is stripped of the entrainer and recycled to the feed—while the lighter phase, with condensate from the stripping, is recycled to the second column. Another early method, called extractive distillation, consists of adding a ternary component that increases ethanol's relative volatility. When the ternary mixture is distilled, it produces anhydrous ethanol on the top stream of the column.

With increasing attention being paid to saving energy, many methods have been proposed that avoid distillation altogether for dehydration. Of these methods, a third method has emerged and has been adopted by the majority of modern ethanol plants. This new process uses molecular sieves to remove water from fuel ethanol. In this process, ethanol vapor under pressure passes through a bed of molecular sieve beads. The bead's pores are sized to allow adsorption of water while excluding ethanol. After a period of time, the bed is regenerated under vacuum or in the flow of inert atmosphere (e.g. N₂) to remove the adsorbed water. Two beds are often used so that one is available to adsorb water while the other is being regenerated. This dehydration technology can account for energy saving of 3,000 btus/gallon (840 kJ/L) compared to earlier azeotropic distillation.^[26]

Recent research has demonstrated that complete dehydration prior to blending with gasoline is not always necessary. Instead, the azeotropic mixture can be blended directly with gasoline so that liquid-liquid phase equilibrium can assist in the elimination of water. A two-stage counter-current setup of mixer-settler tanks can achieve complete recovery of ethanol into the fuel phase, with minimal energy consumption.^[27]

Post-production water issues

Ethanol is hygroscopic, meaning it absorbs water vapor directly from the atmosphere. Because absorbed water dilutes the fuel value of the ethanol and may cause phase separation of ethanol-gasoline blends (which causes engine stall), containers of ethanol fuels must be kept tightly sealed. This high miscibility with water means that ethanol cannot be efficiently shipped through modern pipelines, like liquid hydrocarbons, over long distances.^[28]

The fraction of water that an ethanol-gasoline fuel can contain without phase separation increases with the percentage of ethanol.^[29] For example, E30 can have up to about 2% water. If there is more than about 71% ethanol, the remainder can be any proportion of water or gasoline and phase separation does not occur. The fuel mileage declines with increased water content. The increased solubility of water with higher ethanol content permits E30 and hydrated ethanol to be put in the same tank since any combination of them always results in a single phase. Somewhat less water is tolerated at lower temperatures. For E10 it is about 0.5% v/v at 21° C and decreases to about 0.23% v/v at −34° C .^[30]

Consumer production systems

While biodiesel production systems have been marketed to home and business users for many years, commercialized ethanol production systems designed for end-consumer use have lagged in the marketplace. In 2008, two different companies announced home-scale ethanol production systems. The AFS125 Advanced Fuel System^[31] from Allard Research and Development is capable of producing both ethanol and biodiesel in one machine, while the E-100 MicroFueler^[32] from E-Fuel Corporation is dedicated to ethanol only.

Engines

Fuel economy

Ethanol contains approx. 34% less energy per unit volume than gasoline, and therefore in theory, burning pure ethanol in a vehicle reduces miles per US gallon 34%, given the same fuel economy, compared to burning pure gasoline. However, since ethanol has a higher octane rating, the engine can be made more efficient by raising its compression ratio. Using a variable geometry or twin scroll turbocharger, the compression ratio can be optimized for the fuel, making fuel economy almost constant for any blend.^[33]^[34]

For E10 (10% ethanol and 90% gasoline), the effect is small (~3%) when compared to conventional gasoline,^[35] and even smaller (1–2%) when compared to oxygenated and reformulated blends.^[36] For E85 (85% ethanol), the effect becomes significant. E85 produces lower mileage than gasoline, and requires more frequent refueling. Actual performance may vary depending on the vehicle. Based on EPA tests for all 2006 E85 models, the average fuel economy for E85 vehicles was 25.56% lower than unleaded gasoline.^[37] The EPA-rated mileage of current United States flex-fuel vehicles^[38] should be considered when making price comparisons, but E85 is a high performance fuel, with an octane rating of about 94–96, and should be compared to premium.^[39]

Cold start during the winter

High ethanol blends present a problem to achieve enough vapor pressure for the fuel to evaporate and spark the ignition during cold weather (since ethanol tends to increase fuel enthalpy of vaporization^[40]). When vapor pressure is below 45 kPa starting a cold engine becomes difficult.^[41] To avoid this problem at temperatures below {{convert|11|C|F|lk=on}}, and to reduce ethanol higher emissions during cold weather, both the US and the European markets adopted E85 as the maximum blend to be used in their flexible fuel vehicles, and they are optimized to run at such a blend. At places with harsh cold weather, the ethanol blend in the US has a seasonal reduction to E70 for these very cold regions, though it is still sold as E85.^[42]^[43] At places where temperatures fall below {{convert|-12|C|F|lk=on}} during the winter, it is recommended to install an engine heater system, both for gasoline and E85 vehicles. Sweden has a similar seasonal reduction, but the ethanol content in the blend is reduced to E75 during the winter months.^[43]^[44]

Brazilian flex fuel vehicles can operate with ethanol mixtures up to E100, which is hydrous ethanol (with up to 4% water), which causes vapor pressure to drop faster as compared to E85 vehicles. As a result, Brazilian flex vehicles are built with a small secondary gasoline reservoir located near the engine. During a cold start pure gasoline is injected to avoid starting problems at low temperatures. This provision is particularly necessary for users of Brazil's southern and central regions, where temperatures normally drop below {{convert|15|C|F|lk=on}} during the winter. An improved flex engine generation was launched in 2009 that eliminates the need for the secondary gas storage tank.^[45]^[46] In March 2009 Volkswagen do Brasil launched the Polo E-Flex, the first Brazilian flex fuel model without an auxiliary tank for cold start.^[47]^[48]

Fuel mixtures

In many countries cars are mandated to run on mixtures of ethanol. All Brazilian light-duty vehicles are built to operate for an ethanol blend of up to 25% (E25), and since 1993 a federal law requires mixtures between 22% and 25% ethanol, with 25% required as of mid July 2011.^[49] In the United States all light-duty vehicles are built to operate normally with an ethanol blend of 10% (E10). At the end of 2010 over 90 percent of all gasoline sold in the U.S. was blended with ethanol.^[50] In January 2011 the U.S. Environmental Protection Agency (EPA) issued a waiver to authorize up to 15% of ethanol blended with gasoline (E15) to be sold only for cars and light pickup trucks with a model year of 2001 or newer.^[51]^[52]

Beginning with the model year 1999, an increasing number of vehicles in the world are manufactured with engines that can run on any fuel from 0% ethanol up to 100% ethanol without modification. Many cars and light trucks (a class containing minivans, SUVs and pickup trucks) are designed to be flexible-fuel vehicles using ethanol blends up to 85% (E85) in North America and Europe, and up to 100% (E100) in Brazil. In older model years, their engine systems contained alcohol sensors in the fuel and/or oxygen sensors in the exhaust that provide input to the engine control computer to adjust the fuel injection to achieve stochiometric (no residual fuel or free oxygen in the exhaust) air-to-fuel ratio for any fuel mix. In newer models, the alcohol sensors have been removed, with the computer using only oxygen and airflow sensor feedback to estimate alcohol content. The engine control computer can also adjust (advance) the ignition timing to achieve a higher output without pre-ignition when it predicts that higher alcohol percentages are present in the fuel being burned. This method is backed up by advanced knock sensors – used in most high performance gasoline engines regardless of whether they are designed to use ethanol or not – that detect pre-ignition and detonation.

Other engine configurations

Since 1989 there have also been ethanol engines based on the diesel principle operating in Sweden.^[53] They are used primarily in city buses, but also in distribution trucks and waste collectors. The engines, made by Scania, have a modified compression ratio, and the fuel (known as ED95) used is a mix of 93.6% ethanol and 3.6% ignition improver, and 2.8% denaturants.^[54] The ignition improver makes it possible for the fuel to ignite in the diesel combustion cycle. It is then also possible to use the energy efficiency of the diesel principle with ethanol. These engines have been used in the United Kingdom by Reading Buses but the use of bioethanol fuel is now being phased out.

A 2004 MIT study and an earlier paper published by the Society of Automotive Engineers identified a method to exploit the characteristics of fuel ethanol substantially more efficiently than mixing it with gasoline. The method presents the possibility of leveraging the use of alcohol to achieve definite improvement over the cost-effectiveness of hybrid electric. The improvement consists of using dual-fuel direct-injection of pure alcohol (or the azeotrope or E85) and gasoline, in any ratio up to 100% of either, in a turbocharged, high compression-ratio, small-displacement engine having performance similar to an engine having twice the displacement. Each fuel is carried separately, with a much smaller tank for alcohol. The high-compression (for higher efficiency) engine runs on ordinary gasoline under low-power cruise conditions. Alcohol is directly injected into the cylinders (and the gasoline injection simultaneously reduced) only when necessary to suppress ‘knock’ such as when significantly accelerating. Direct cylinder injection raises the already high octane rating of ethanol up to an effective 130. The calculated over-all reduction of gasoline use and CO₂ emission is 30%. The consumer cost payback time shows a 4:1 improvement over turbo-diesel and a 5:1 improvement over hybrid. The problems of water absorption into pre-mixed gasoline (causing phase separation), supply issues of multiple mix ratios and cold-weather starting are also avoided.^[55]^[56]

In a 2008 study, complex engine controls and increased exhaust gas recirculation allowed a compression ratio of 19.5 with fuels ranging from neat ethanol to E50. Thermal efficiency up to approximately that for a diesel was achieved.^[57] This would result in the fuel economy of a neat ethanol vehicle to be about the same as one burning gasoline.

In June 2016, Nissan announced plans to develop fuel cell vehicles powered by ethanol rather than hydrogen, the fuel of choice by the other car manufacturers that have developed and commercialized fuel cell vehicles, such as the Hyundai Tucson FCEV, Toyota Mirai, and Honda FCX Clarity. The main advantage of this technical approach is that it would be cheaper and easier to deploy the fueling infrastructure than setting up the one required to deliver hydrogen at high pressures, as each hydrogen fueling station cost {{USD|1 million}} to {{USD|2 million}} to build.^[62]

Nissan plans to create a technology that uses liquid ethanol fuel as a source to generate hydrogen within the vehicle itself. The technology uses heat to reform ethanol into hydrogen to feed what is known as a solid oxide fuel cell (SOFC). The fuel cell generates electricity to supply power to the electric motor driving the wheels, through a battery that handles peak power demands and stores regenerated energy. The vehicle would include a tank for a blend of water and ethanol, which is fed into an onboard reformer that splits it into pure hydrogen and carbon dioxide. According to Nissan, the liquid fuel could be an ethanol-water blend at a 55:45 ratio. Nissan expects to commercialize its technology by 2020.^[58]

Experience by country

The world's top ethanol fuel producers in 2011 were the United States with {{convert|13.9e9|USgal|L impgal|abbr=none|sp=us|lk=on}} and Brazil with {{convert|5.6e9|USgal|L impgal|abbr=none|sp=us}}, accounting together for 87.1% of world production of {{convert|22.36e9|USgal|L impgal|abbr=none|sp=us}}.^[2] Strong incentives, coupled with other industry development initiatives, are giving rise to fledgling ethanol industries in countries such as Germany, Spain, France, Sweden, China, Thailand, Canada, Colombia, India, Australia, and some Central American countries.

Environment

Energy balance

All biomass goes through at least some of these steps: it needs to be grown, collected, dried, fermented, distilled, and burned. All of these steps require resources and an infrastructure. The total amount of energy input into the process compared to the energy released by burning the resulting ethanol fuel is known as the energy balance (or "energy returned on energy invested"). Figures compiled in a 2007 report by National Geographic Magazine^[63] point to modest results for corn ethanol produced in the US: one unit of fossil-fuel energy is required to create 1.3 energy units from the resulting ethanol. The energy balance for sugarcane ethanol produced in Brazil is more favorable, with one unit of fossil-fuel energy required to create 8 from the ethanol. Energy balance estimates are not easily produced, thus numerous such reports have been generated that are contradictory. For instance, a separate survey reports that production of ethanol from sugarcane, which requires a tropical climate to grow productively, returns from 8 to 9 units of energy for each unit expended, as compared to corn, which only returns about 1.34 units of fuel energy for each unit of energy expended.^[64] A 2006 University of California Berkeley study, after analyzing six separate studies, concluded that producing ethanol from corn uses much less petroleum than producing gasoline.^[65]

When compared to gasoline, depending on the production method, ethanol releases less greenhouse gases.^[67]^[68]

Air pollution

Compared with conventional unleaded gasoline, ethanol is a particulate-free burning fuel source that combusts with oxygen to form carbon dioxide, carbon monoxide, water and aldehydes. The Clean Air Act requires the addition of oxygenates to reduce carbon monoxide emissions in the United States. The additive MTBE is currently being phased out due to ground water contamination, hence ethanol becomes an attractive alternative additive. Current production methods include air pollution from the manufacturer of macronutrient fertilizers such as ammonia.

A study by atmospheric scientists at Stanford University found that E85 fuel would increase the risk of air pollution deaths relative to gasoline by 9% in Los Angeles, US: a very large, urban, car-based metropolis that is a worst-case scenario.^[69] Ozone levels are significantly increased, thereby increasing photochemical smog and aggravating medical problems such as asthma.^[70]^[71]

Brazil burns significant amounts of ethanol biofuel. Gas chromatograph studies were performed of ambient air in São Paulo, Brazil, and compared to Osaka, Japan, which does not burn ethanol fuel. Atmospheric Formaldehyde was 160% higher in Brazil, and Acetaldehyde was 260% higher.^[72]{{update after|2016|9|14}}

Carbon dioxide

The graph on the right shows figures calculated by the UK government for the purposes of the Renewable transport fuel obligation.^[73]

The January 2006 Science article from UC Berkeley's ERG, estimated reduction from corn ethanol in GHG to be 13% after reviewing a large number of studies. In a correction to that article released shortly after publication, they reduce the estimated value to 7.4%. A National Geographic Magazine overview article (2007)^[63] puts the figures at 22% less CO₂ emissions in production and use for corn ethanol compared to gasoline and a 56% reduction for cane ethanol. Carmaker Ford reports a 70% reduction in CO₂ emissions with bioethanol compared to petrol for one of their flexible-fuel vehicles.^[74]

An additional complication is that production requires tilling new soil^[75] which produces a one-off release of GHG that it can take decades or centuries of production reductions in GHG emissions to equalize.^[76] As an example, converting grass lands to corn production for ethanol takes about a century of annual savings to make up for the GHG released from the initial tilling.^[75]

Change in land use

Large-scale farming is necessary to produce agricultural alcohol and this requires substantial amounts of cultivated land. University of Minnesota researchers report that if all corn grown in the U.S. were used to make ethanol it would displace 12% of current U.S. gasoline consumption.^[77] There are claims that land for ethanol production is acquired through deforestation, while others have observed that areas currently supporting forests are usually not suitable for growing crops.^[78]^[79] In any case, farming may involve a decline in soil fertility due to reduction of organic matter,^[80] a decrease in water availability and quality, an increase in the use of pesticides and fertilizers, and potential dislocation of local communities.^[81] New technology enables farmers and processors to increasingly produce the same output using less inputs.^[77]

Cellulosic ethanol production is a new approach that may alleviate land use and related concerns. Cellulosic ethanol can be produced from any plant material, potentially doubling yields, in an effort to minimize conflict between food needs vs. fuel needs. Instead of utilizing only the starch by-products from grinding wheat and other crops, cellulosic ethanol production maximizes the use of all plant materials, including gluten. This approach would have a smaller carbon footprint because the amount of energy-intensive fertilisers and fungicides remain the same for higher output of usable material. The technology for producing cellulosic ethanol is currently in the commercialization stage.^[17]^[18]

Using biomass for electricity instead of ethanol

Converting biomass to electricity for charging electric vehicles may be a more "climate-friendly" transportation option than using biomass to produce ethanol fuel, according to an analysis published in Science in May 2009^[82] Researchers continue to search for more cost-effective developments in both cellulosic ethanol and advanced vehicle batteries.^[83]

Health costs of ethanol emissions

For each billion ethanol-equivalent gallons of fuel produced and combusted in the US, the combined climate-change and health costs are $469 million for gasoline, $472–952 million for corn ethanol depending on biorefinery heat source (natural gas, corn stover, or coal) and technology, but only $123–208 million for cellulosic ethanol depending on feedstock (prairie biomass, Miscanthus, corn stover, or switchgrass).^[84]

Efficiency of common crops

As ethanol yields improve or different feedstocks are introduced, ethanol production may become more economically feasible in the US. Currently, research on improving ethanol yields from each unit of corn is underway using biotechnology. Also, as long as oil prices remain high, the economical use of other feedstocks, such as cellulose, become viable. By-products such as straw or wood chips can be converted to ethanol. Fast growing species like switchgrass can be grown on land not suitable for other cash crops and yield high levels of ethanol per unit area.^[63]

Reduced petroleum imports and costs

One rationale given for extensive ethanol production in the U.S. is its benefit to energy security, by shifting the need for some foreign-produced oil to domestically produced energy sources.^[92]^[93] Production of ethanol requires significant energy, but current U.S. production derives most of that energy from coal, natural gas and other sources, rather than oil.^[94] Because 66% of oil consumed in the U.S. is imported, compared to a net surplus of coal and just 16% of natural gas (figures from 2006),^[95] the displacement of oil-based fuels to ethanol produces a net shift from foreign to domestic U.S. energy sources.

According to a 2008 analysis by Iowa State University, the growth in US ethanol production has caused retail gasoline prices to be US $0.29 to US $0.40 per gallon lower than would otherwise have been the case.^[96]

Motorsport

Leon Duray qualified third for the 1927 Indianapolis 500 auto race with an ethanol-fueled car.^[97] The IndyCar Series adopted a 10% ethanol blend for the 2006 season, and a 98% blend in 2007.

In drag racing, there are Top Alcohol classes for dragsters and funny cars since the 1970s.

The American Le Mans Series sports car championship introduced E10 in the 2007 season to replace pure gasoline. In the 2008 season, E85 was allowed in the GT class and teams began switching to it.^[98]

In 2011, the three national NASCAR stock car series mandated a switch from gasoline to E15, a blend of Sunoco GTX unleaded racing fuel and 15% ethanol.^[99]

Ethanol fuel may also be utilized as a rocket fuel. {{as of|2010}}, small quantities of ethanol are used in lightweight rocket-racing aircraft.^[100]

Replacement cooking fuel

Research

Ethanol research focuses on alternative sources, novel catalysts and production processes. INEOS produced ethanol from vegetative material and wood waste.^[102] The bacterium E.coli when genetically engineered with cow rumen genes and enzymes can produce ethanol from corn stover.^[103] Other potential feedstocks are municipal waste, recycled products, rice hulls, sugarcane bagasse, wood chips, switchgrass and carbon dioxide.^[104]^[105]

Bibliography

See also

References

1. ^{{cite web|url=http://www.unep.fr/scp/rpanel/pdf/Assessing_Biofuels_Full_Report.pdf |title=Towards Sustainable Production and Use of Resources: Assessing Bio fuels |date=16 October 2009 |access-date=24 October 2009 |publisher=United Nations Environment Programme |deadurl=yes |archiveurl=https://web.archive.org/web/20091122133933/http://www.unep.fr/scp/rpanel/pdf/Assessing_Biofuels_Full_Report.pdf |archivedate=22 November 2009 |df=dmy }}
2. ^AMIS Market Monitor No. 48 – May 2017, http://www.amis-outlook.org/fileadmin/user_upload/amis/docs/Market_monitor/AMIS_Market_Monitor_Issue_47.pdf
3. ^{{cite web |url= http://www.afdc.energy.gov/laws/4274|title = Gasoline Gallon Equivalent (GGE) Definition |publisher= energy.gov |accessdate= 12 October 2011}}
4. ^{{Cite web|url=https://www.afdc.energy.gov/fuels/fuel_comparison_chart.pdf|title=Alternative Fuels Data Center – Fuel Properties Comparison|last=|first=|date=2014-10-29|website=Alternative Fuels Data Center|archive-url=|archive-date=|dead-url=|access-date=}}
5. ^{{cite web|url=http://images1.americanprogress.org/il80web20037/americanenergynow/AmericanEnergy.pdf|title=The Renewable Path to Energy Security|publisher=Images1.americanprogress.org|accessdate=20 January 2015}}
6. ^{{cite web|url=http://extranet.agricultura.gov.br/sislegis-consulta/consultarLegislacao.do?operacao=visualizar&id=17886|title=Portaria Nº 143, de 27 de Junho de 2007|publisher=Ministério da Agricultura, Pecuária e Abastecimento|accessdate=5 October 2008|language=Portuguese}}
7. ^{{cite web |url=http://www.virapagina.com.br/anfavea2011/|title= Anúario da Industria Automobilistica Brasileira 2011: Tabela 2.3 Produção por combustível – 1957/2010|publisher=ANFAVEA – Associação Nacional dos Fabricantes de Veículos Automotores (Brasil)|accessdate=22 January 2012|language=Portuguese}} pp. 62–63.
8. ^{{cite web |url=http://www.anfavea.com.br/cartas/Carta308.pdf |title=Licenciamento total de automóveis e comerciais leves por combustível |trans-title=Total automobiles and light-trucks registered by fuel |language=Portuguese |author=Renavam/Denatran |publisher=ANFAVEA |date=January 2012 |accessdate=21 January 2012 |deadurl=yes |archiveurl=https://web.archive.org/web/20120131115223/http://www.anfavea.com.br/cartas/Carta308.pdf |archivedate=31 January 2012 |df=dmy }} Carta de ANFAVEA 308 pp. 4.
9. ^{{cite web|url=http://unica.com.br/noticias/show.asp?nwsCode=4771CECF-FDB8-43B5-9CF9-E342B99F5C23|archive-url=https://archive.is/20121205031059/http://unica.com.br/noticias/show.asp?nwsCode=4771CECF-FDB8-43B5-9CF9-E342B99F5C23|dead-url=yes|archive-date=5 December 2012|title=Motos flex foram as mais vendidas em 2009 na categoria 150cc|author=Abraciclo|publisher=UNICA|date=27 January 2010|accessdate=10 February 2010 |language=Portuguese}}
10. ^{{cite web|url=http://www.abraciclo.com.br/images/stories/dados_setor/motocicletas/producao/2010%20produo-dezcorreto.pdf|title=Produção Motocicletas 2010|publisher=ABRACICLO|accessdate=5 February 2011|language=Portuguese}}
11. ^{{cite web|url=http://www.abraciclo.com.br/images/stories/dados_setor/motocicletas/producao/2011%20produo-dezembro.pdf|title=Produção Motocicletas 2011|trans-title=2011 Motorcycle Production|publisher=ABRACICLO|accessdate=21 January 2012|language=Portuguese}}
12. ^{{cite web|url=http://www.efrc.com/manage/authincludes/article_uploads/Deforestation%20diesel1.pdf |title=Deforestation diesel – the madness of biofuel |accessdate=27 August 2011}}
13. ^Youngquist, W. Geodestinies, National Book Company, Portland, Oregon, p.499
14. ^{{cite web|url=http://www.oilcrash.com/articles/pf_bio.htm |title=The dirty truth about biofuels |publisher=Oilcrash.com |date=14 March 2005 |accessdate=27 August 2011}}
15. ^{{cite news|last=Kinver |first=Mark |url=http://news.bbc.co.uk/2/hi/science/nature/5353118.stm |title=Biofuels look to the next generation |work=BBC News |date=18 September 2006 |accessdate=27 August 2011}}
16. ^{{cite journal|doi=10.1039/b822951c|author1=O. R. Inderwildi |author2=D. A. King |title=Quo Vadis Biofuels|year=2009|journal=Energy & Environmental Science|volume=2|page=343|issue=4}}
17. ^¹{{cite web |url=http://bio.org/ind/biofuel/CellulosicEthanolIssueBrief.pdf |title=Industrial & Environmental |publisher=Bio.org |accessdate=20 January 2015 |deadurl=yes |archiveurl=https://web.archive.org/web/20060212025744/http://www.bio.org/ind/biofuel/CellulosicEthanolIssueBrief.pdf |archivedate=12 February 2006 |df=dmy-all }}
18. ^¹{{cite web|url=http://www.worldenergyoutlook.org/summaries2006/English.pdf |title=World Energy Outlook 2006 |publisher=Worldenergyoutlook.org |accessdate=20 January 2015 |deadurl=yes |archiveurl=https://web.archive.org/web/20070928041451/http://www.worldenergyoutlook.org/summaries2006/English.pdf |archivedate=28 September 2007 }}
19. ^{{cite web|url=http://www.meti.go.jp/report/downloadfiles/g30819b40j.pdf|title=World Fuel Ethanol Analysis and Outlook|publisher=Meti.go.jp|accessdate=20 January 2015|deadurl=yes|archiveurl=https://web.archive.org/web/20160328142005/http://www.meti.go.jp/report/downloadfiles/g30819b40j.pdf|archivedate=28 March 2016|df=dmy-all}}
20. ^{{cite web|url=http://www.grainscouncil.com/Policy/Biofuels/Qld_Biofuels_study.pdf |archiveurl=https://web.archive.org/web/20080718185555/http://www.grainscouncil.com/Policy/Biofuels/Qld_Biofuels_study.pdf |archivedate=18 July 2008 |title=(grainscouncil.com, Biofuels_study 268 kB pdf, footnote, p 6) |date=18 July 2008 |accessdate=27 August 2011}}
21. ^ {{webarchive|url=https://web.archive.org/web/20080509182640/http://www.ethanolproducer.com/article-print.jsp?article_id=2077|date=9 May 2008}}
22. ^{{cite web|author=Martin LaMonica |url=http://news.cnet.com/8301-11128_3-9966867-54.html |title=Algae farm in Mexico to produce ethanol in '09 |publisher=News.cnet.com |date=12 June 2008 |accessdate=27 August 2011}}
23. ^{{cite web|url=http://www.greencarcongress.com/2005/06/new_enzyme_for_.html|title=New Enzyme for More Efficient Corn Ethanol Production|date=30 June 2005|publisher=Green Car Congress|accessdate=14 January 2008}}
24. ^{{cite web|title=Ethanol|url=https://web.extension.illinois.edu/ethanol/|website=University of Illinois Extension|accessdate=10 July 2017}}
25. ^{{cite conference |first=Orlando |last=Volpato Filho |url=https://www.researchgate.net/publication/309564235_GASOLINE_C_MADE_WITH_HYDROUS_ETHANOL |title=Gasoline C made with Hydrous Ethanol |date=September 2008 |conference=XVI SIMEA 2008 - Simpósio Internacional de Engenharia Automotiva |location=Sao Paolo |accessdate=10 July 2017}}
26. ^{{cite web|url=http://www.bioethanol.ru/images/bioethanol/Fuel%20ethanol%20production%20-%20Katzen.pdf|title=Modern Corn Ethanol plant description}}
27. ^{{Cite journal|last=Stacey|first=Neil T.|last2=Hadjitheodorou|first2=Aristoklis|last3=Glasser|first3=David|date=2016-09-19|title=Gasoline Preblending for Energy-Efficient Bioethanol Recovery|journal=Energy & Fuels|language=EN|volume=30|issue=10|pages=8286–8291|doi=10.1021/acs.energyfuels.6b01591|issn=0887-0624}}
28. ^W. Horn and F. Krupp. Earth: The Sequel: The Race to Reinvent Energy and Stop Global Warming. 2006, 85
29. ^This is shown for 25 °C (77 °F) in a gasoline-ethanol-water phase diagram, Fig 13 of {{cite web|url=http://www.vtt.fi/inf/julkaisut/muut/2004/EtOH_VTT5100_03.pdf|title=Technical View on Biofuels for Transportation – Focus on Ethanol End-Use Aspects|author= Päivi Aakko|author2=Nils-Olof Nylund|accessdate=14 January 2008 |archiveurl=https://web.archive.org/web/20071203173845/http://www.vtt.fi/inf/julkaisut/muut/2004/EtOH_VTT5100_03.pdf |archivedate=3 December 2007}}
30. ^{{cite web|url=http://www.epa.gov/OMS/regs/fuels/rfg/waterphs.pdf|title=Water Phase Separation in Oxygenated Gasoline|publisher=Epa.gov|accessdate=20 January 2015|deadurl=yes|archiveurl=https://web.archive.org/web/20150209040136/http://epa.gov/oms/regs/fuels/rfg/waterphs.pdf|archivedate=9 February 2015|df=dmy-all}}
31. ^{{cite web|url=http://gas2.org/2008/11/04/home-mini-refinery-makes-ethanol-biodiesel-simultaneously/#more-1219|title=Home Mini-Refinery Makes Ethanol & Biodiesel Simultaneously|date=4 November 2008|publisher=Gas2.0|accessdate=4 November 2008}}
32. ^{{cite web|url=http://www.popularmechanics.com/blogs/science_news/4262690.html|title=Micro Fueler Is First Ethanol Kit for Brewing Backyard Biofuels on the Cheap|date=8 May 2008|publisher=PopularMechanics|accessdate=8 May 2008|archive-url=https://web.archive.org/web/20080509083826/http://www.popularmechanics.com/blogs/science_news/4262690.html|archive-date=9 May 2008|dead-url=yes|df=dmy-all}}
33. ^{{cite web|url=http://www.afdc.energy.gov/afdc/ethanol/|title=Alternative Fuels Data Center: Ethanol|publisher=Afdc.energy.gov|accessdate=20 January 2015}}
34. ^{{cite web |url=http://www.eia.doe.gov/cneaf/solar.renewables/alt_trans_fuel/attf.pdf#page=39 |title=U.S. Energy Information Administration (EIA) |accessdate=2016-02-09 |deadurl=yes |archiveurl=https://web.archive.org/web/20080821085349/http://www.eia.doe.gov/#page=39 |archivedate=21 August 2008 |df=dmy }}
35. ^{{cite web|url=http://www.raa.net/page.asp?TerID=146 |title=Ethanol in Petrol |date=February 2004 |publisher=Royal Automobile Association of South Australia |accessdate=29 April 2007 |deadurl=yes |archiveurl=https://web.archive.org/web/20070609142818/http://www.raa.net/page.asp?TerID=146 |archivedate=9 June 2007 }}
36. ^{{cite web|url=http://www.epa.gov/orcdizux/rfgecon.htm |title=EPA Info |publisher=US EPA |date=7 March 2011 |accessdate=27 August 2011 |deadurl=yes |archiveurl=https://web.archive.org/web/20090625042029/http://www.epa.gov/orcdizux/rfgecon.htm |archivedate=25 June 2009 }}
37. ^¹²{{Cite book|author1=J. Goettemoeller |author2=A. Goettemoeller |title=Sustainable Ethanol: Biofuels, Biorefineries, Cellulosic Biomass, Flex-Fuel Vehicles, and Sustainable Farming for Energy Independence|year=2007|publisher=Prairie Oak Publishing, Maryville, Missouri|page=42|isbn=978-0-9786293-0-4}}
38. ^{{cite web|url=http://www.fueleconomy.gov/feg/byfueltype.htm|title=EPA Mileage |publisher=Fueleconomy.gov |accessdate=27 August 2011}}
39. ^{{cite web |url=http://www.ethanolrfa.org/page/-/rfa-association-site/ChangesinGasolineManualIV-UpdatedLogo.pdf |title=Changes in Gasoline IV, sponsored by Renewable Fuels Foundation |accessdate=27 August 2011 |deadurl=yes |archiveurl=http://webarchive.loc.gov/all/20120802001152/http://www.ethanolrfa.org/page/-/rfa-association-site/ChangesinGasolineManualIV-UpdatedLogo.pdf |archivedate=2 August 2012 |df=dmy-all }}
40. ^{{cite journal|journal=Fuel|doi=10.1016/j.fuel.2006.08.008|title=Molar enthalpy of vaporization of ethanol–gasoline mixtures and their colloid state|year=2007|volume = 86|page=323|author=Roman M. Balabin|issue=3|display-authors=etal}}
41. ^{{cite web|url=http://royalsociety.org/displaypagedoc.asp?id=28632 |title=Sustainable biofuels: prospects and challenges |date=January 2008 |format=PDF |publisher=The Royal Society |accessdate=27 September 2008 |deadurl=yes |archiveurl=https://web.archive.org/web/20081005001713/http://royalsociety.org/displaypagedoc.asp?id=28632 |archivedate=5 October 2008 }} Policy document 01/08. See 4.3.1 Vapour pressure and bioethanol and Figure 4.3 for the relation between ethanol content and vapor pressure.
42. ^{{cite web|url=http://www.autobloggreen.com/2007/02/27/when-is-e85-not-85-percent-ethanol-when-its-e70-with-an-e85-st/|title=When is E85 not 85 percent ethanol? When it's E70 with an E85 sticker on it|author1=Ethanol Promotion |author2=Information Council |publisher=AutoblogGreen|date=27 February 2007|accessdate=24 August 2008}}
43. ^¹{{cite web|url=http://interestingenergyfacts.blogspot.com/2008/09/ethanol-fuel-and-cars.html|title=Ethanol fuel and cars|publisher=Interesting Energy Facts|accessdate=23 September 2008|date=2008-09-23}}
44. ^{{cite web|url=http://ec.europa.eu/enterprise/automotive/mveg_meetings/subgroup_euro/meeting9/swedish_comments_on_draft_v4.pdf|archiveurl=https://web.archive.org/web/20081003062351/http://ec.europa.eu/enterprise/automotive/mveg_meetings/subgroup_euro/meeting9/swedish_comments_on_draft_v4.pdf|archivedate=3 October 2008|work=ec.europa.eu|title=Swedish comments on Euro 5/6 comitology version 4, 30 May 2007: Cold Temperature Tests For Flex Fuel Vehicles|publisher=European Commission|author=Vägverket (Swedish Road Administration)|date=30 May 2007|accessdate=23 September 2008}}
45. ^{{cite journal|url=http://cenbio.iee.usp.br/download/revista/RBB3.pdf |title=Here comes the 'Flex' vehicles third generation |journal=Revista Brasileira de BioEnergia |date=August 2008 |accessdate=23 September 2008 |language=Portuguese, English |deadurl=yes |archiveurl=https://web.archive.org/web/20081003062358/http://cenbio.iee.usp.br/download/revista/RBB3.pdf |archivedate=3 October 2008 |df=dmy }} Ano 2, No. 3 (every article is presented in both English and Portuguese)
46. ^{{cite news |url=http://portal.rpc.com.br/gazetadopovo/economia/conteudo.phtml?tl=1&id=774927&tit= |title=Bosch investe na segunda geração do motor flex |publisher=Gazeta do Povo |author=Agência Estado |date=10 June 2008 |accessdate=23 September 2008 |language=Portuguese, English |deadurl=yes |archiveurl=https://web.archive.org/web/20090110180712/http://portal.rpc.com.br/gazetadopovo/economia/conteudo.phtml?tl=1&id=774927&tit= |archivedate=10 January 2009 |df=dmy }}
47. ^{{cite news |url=http://quatrorodas.abril.com.br/carros/lancamentos/volkswagen-polo-e-flex-425390.shtml |author=Q. Rodas |publisher=Editora Abril |title=Volkswagen Polo E-Flex |date=March 2009 |accessdate=12 March 2003 |language=Portuguese |deadurl=yes |archiveurl=https://web.archive.org/web/20090307000657/http://quatrorodas.abril.com.br/carros/lancamentos/volkswagen-polo-e-flex-425390.shtml |archivedate=7 March 2009 |df=dmy }}
48. ^{{cite web|url=http://www.unica.com.br/noticias/show.asp?nwsCode=0548296D-D8CE-4E25-9973-BF18D30BDFFD|archive-url=https://archive.is/20121206040122/http://www.unica.com.br/noticias/show.asp?nwsCode=0548296D-D8CE-4E25-9973-BF18D30BDFFD|dead-url=yes|archive-date=6 December 2012|publisher=UNICA|title=Volks lança sistema que elimina tanquinho de gasolina para partida a frio|date=12 March 2009|accessdate=12 March 2003|language=Portuguese}}
49. ^{{cite journal|url=http://www.teses.usp.br/teses/disponiveis/86/86131/tde-07052008-115336/|author=Julieta Andrea Puerto Rico|title=Programa de Biocombustíveis no Brasil e na Colômbia: uma análise da implantação, resultados e perspectivas|publisher=Universidade de São Paulo|date=8 May 2008|language=Portuguese|accessdate=5 October 2008|doi=10.11606/D.86.2007.tde-07052008-115336}} PhD Dissertation Thesis, pp. 81–82
50. ^{{cite web|url=http://www.ethanolrfa.org/page/-/2011%20RFA%20Ethanol%20Industry%20Outlook.pdf?nocdn=1|title=2011 Ethanol Industry Outlook: Building Bridges to a More Sustainable Future|publisher=Renewable Fuels Association|year=2011|accessdate=30 April 2011|deadurl=yes|archiveurl=https://web.archive.org/web/20110928131808/http://www.ethanolrfa.org/page/-/2011%20RFA%20Ethanol%20Industry%20Outlook.pdf?nocdn=1|archivedate=28 September 2011|df=dmy-all}}See pages 2–3, 10–11, 19–20, and 26–27.
51. ^{{cite news|url=https://www.nytimes.com/2010/10/14/business/energy-environment/14ethanol.html?_r=1&emc=eta1|title=A Bit More Ethanol in the Gas Tank|author=Matthew L. Wald|work=The New York Times|date=13 October 2010|accessdate=14 October 2010}}
52. ^{{cite news|url=http://content.usatoday.com/communities/driveon/post/2010/10/epa-to-allow-15-ethanol-in-gasoline-up-from-10-now-/1?POE=click-refer|title=EPA allows 15% ethanol in gasoline, but only for late-model cars|author=Fred Meier|work=USA Today|date=13 October 2010|accessdate=14 October 2010}}
53. ^ Scania PRESSInfo, 21 May 2007 {{webarchive|url=https://web.archive.org/web/20090320033944/http://www.scania.com/Images/P07503EN%20New%20ethanol%20engine_tcm10-163550.pdf|date=20 March 2009}}
54. ^{{cite web|url=http://ethanolproducer.com/article.jsp?article_id=3888|title=Ethanol Producer Magazine – The Latest News and Data About Ethanol Production|publisher=Ethanolproducer.com|accessdate=20 January 2015}}
55. ^{{citation |url=http://www.psfc.mit.edu/library1/catalog/reports/2000/06ja/06ja016/06ja016_full.pdf |title=Direct Injection Ethanol Boosted Gasoline Engines: Biofuel Leveraging for Cost Effective Reduction of Oil Dependence and CO2 Emissions. MIT Report PSFC/JA-06-16 |journal=MIT Energy Initiative |date=April 20, 2005 |last=Cohn |first=D.R. |last2=Bromberg |first2=L. |last3=Heywood |first3=J.B. |accessdate=November 23, 2014 |deadurl=yes |archiveurl=https://web.archive.org/web/20130602080432/http://www.psfc.mit.edu/library1/catalog/reports/2000/06ja/06ja016/06ja016_full.pdf |archivedate=2 June 2013 |df=dmy-all }}
56. ^{{cite book|chapter-url=http://www.sae.org/technical/papers/2000-01-2902 |title=SAE Paper 2001-01-2901 |volume=1 |publisher=Sae.org |date=16 October 2000 |accessdate=27 August 2011|doi=10.4271/2000-01-2902 |chapter=A Gasoline Engine Concept for Improved Fuel Economy -The Lean Boost System |series=SAE Technical Paper Series |last1=Stokes |first1=J. |last2=Lake |first2=T. H. |last3=Osborne |first3=R. J. }}
57. ^{{cite web|url=http://www.epa.gov/otaq/presentations/epa-fev-isaf-no55.pdf|title=Economical, High-Efficiency Engine Technologies for Alcohol Fuels|author1=M. Brusstar |author2=M. Bakenhus | publisher=U.S. Environmental Protection Agency|accessdate=14 January 2008}}
58. ^¹{{cite news| url=http://www.greencarreports.com/news/1104467_nissan-takes-a-different-approach-to-fuel-cells-ethanol | title=Nissan takes a different approach to fuel cells: ethanol | first=John | last=Voelcker | work=Green Car Reports| date=2016-06-14| accessdate=2016-06-16}}
59. ^¹²³⁴{{cite web|url=http://ethanolrfa.3cdn.net/d4ad995ffb7ae8fbfe_1vm62ypzd.pdf|title=Acelerating Industry Innovation – 2012 Ethanol Industry Outlook|author=Renewable Fuels Association|publisher=Renewable Fuels Association|date=6 March 2012|accessdate=18 March 2012|archive-url=https://web.archive.org/web/20120514044111/http://ethanolrfa.3cdn.net/d4ad995ffb7ae8fbfe_1vm62ypzd.pdf|archive-date=14 May 2012|dead-url=yes|df=dmy-all}} See pp. 3, 8, 10 22 and 23.
60. ^{{cite web|url=http://www.ethanolrfa.org/pages/statistics#E|title=Industry Statistics: 2010 World Fuel Ethanol Production|publisher=Renewable Fuels Association|author=F.O. Lichts|accessdate=30 April 2011}}
61. ^{{cite web|url=http://www.ethanolrfa.org/page/-/objects/pdf/outlook/RFAoutlook2010_fin.pdf?nocdn=1 |title=2009 Global Ethanol Production (Million Gallons) |publisher=F.O. Licht, cited in Renewable Fuels Association, Ethanol Industry Overlook 2010, pp. 2 and 22 |year=2010 |accessdate=12 February 2011 |deadurl=yes |archiveurl=https://web.archive.org/web/20110718131036/http://www.ethanolrfa.org/page/-/objects/pdf/outlook/RFAoutlook2010_fin.pdf?nocdn=1 |archivedate=18 July 2011 |df=dmy }}
62. ^{{cite web|url=http://www.ethanolrfa.org/industry/statistics/|archiveurl=https://web.archive.org/web/20080408091334/http://www.ethanolrfa.org/industry/statistics/|archivedate=8 April 2008|title=2007 and 2008 World Fuel Ethanol Production|publisher=Renewable Fuels Association|accessdate=17 April 2010|author=F.O. Licht}}
63. ^¹²³{{cite web|url=http://ngm.nationalgeographic.com/2007/10/biofuels/biofuels-text|title=Biofuels|author=Joel K. Bourne, Jr.|publisher=Ngm.nationalgeographic.vom|accessdate=20 January 2015}}
64. ^ {{webarchive|url=https://web.archive.org/web/20150908130551/http://www.iea.org/textbase/nppdf/free/2004/biofuels2004.pdf|date=8 September 2015}}
65. ^{{cite web|url=http://www.berkeley.edu/news/media/releases/2006/01/26_ethanol.shtml|title=01.26.2006 - Ethanol can replace gasoline with significant energy savings, comparable impact on greenhouse gases|publisher=Berkeley.edu|accessdate=20 January 2015}}
66. ^{{cite web |url=http://www.oregon.gov/ENERGY/RENEW/Biomass/forum.shtml |title=oregon.gov, biomass forum |publisher=Oregon.gov |date=27 March 2009 |accessdate=27 August 2011 |deadurl=yes |archiveurl=https://web.archive.org/web/20110828095351/http://www.oregon.gov/ENERGY/RENEW/Biomass/forum.shtml |archivedate=28 August 2011 |df=dmy-all }}
67. ^{{cite web|url=http://www.transportation.anl.gov/pdfs/TA/58.pdf|title=Effects of Fuel Ethanol Use on Fuel-Cycle Energy and Greenhouse Gas Emissions|accessdate=7 July 2009|publisher=Argonne National Laboratory|author1=M. Wang |author2=C. Saricks |author3=D. Santini }}
68. ^{{cite web|url=http://www.transportation.anl.gov/pdfs/TA/271.pdf|author=M. Wang|accessdate=7 July 2009|title=Energy and Greenhouse Gas Emissions Effects of Fuel Ethanol}}
69. ^{{cite news|work=San Francisco Chronicle|date=18 April 2007|url=http://sfgate.com/cgi-bin/article.cgi?file=/c/a/2007/04/18/MNG7EPAN601.DTL|title=Study warns of health risk from ethanol|accessdate=7 July 2009 | first=Keay | last=Davidson}}
70. ^{{cite web|url=http://pubs.acs.org/subscribe/journals/esthag-w/2007/apr/science/ee_ethanol.html|archive-url=https://wayback.archive-it.org/all/20081027033132/http://pubs.acs.org/subscribe/journals/esthag-w/2007/apr/science/ee_ethanol.html|dead-url=yes|archive-date=27 October 2008|title=Clearing the air on ethanol|date=18 April 2007|publisher=Environmental Science & Technology|accessdate=14 January 2008|df=dmy-all}}
71. ^{{cite web|url=http://pubs.acs.org/cgi-bin/sample.cgi/esthag/asap/html/es062085v.html|title=Effects of Ethanol (E85) vs. Gasoline Vehicles on Cancer and Mortality in the United States|author=M. Z. Jacobson|date=14 March 2007|publisher=ACS Publications|accessdate=14 January 2008}}
72. ^{{Cite journal | url=https://www.researchgate.net/publication/240399720 | doi=10.1016/S1352-2310(01)00136-4| title=Atmospheric alcohols and aldehydes concentrations measured in Osaka, Japan and in Sao Paulo, Brazil| journal=Atmospheric Environment| volume=35| issue=18| pages=3075–3083| year=2001| last1=Nguyen| first1=H.}}
73. ^¹²{{cite web|url=http://www.dft.gov.uk/pgr/roads/environment/rtfo/govrecrfa.pdf |archive-url=http://webarchive.nationalarchives.gov.uk/20161124161624/http://www.dft.gov.uk/pgr/roads/environment/rtfo/govrecrfa.pdf |archive-date=24 November 2016 |title=Part One |accessdate=27 August 2011 |deadurl=yes }}
74. ^{{cite web|url=http://www.eubia.org/fileadmin/template/main/res/pics/projects/RESTMAC_-_Bioethanol_Production___Use.pdf|archiveurl=https://web.archive.org/web/20071128055459/http://www.eubia.org/fileadmin/template/main/res/pics/projects/RESTMAC_-_Bioethanol_Production___Use.pdf|archivedate=28 November 2007|title=Bioethanol Production and Use Creating Markets for Renewable Energy Technologies|work=eubia.org|publisher= EU, RES Technology Marketing Campaign, European Biomass Industry Association EUBIA|year= 2007}}
75. ^¹{{cite news|url=https://www.nytimes.com/2008/02/08/science/earth/08wbiofuels.html?em&ex=1202792400&en=b90a6c6cca379cde&ei=5087%0A|title=Biofuels Deemed a Greenhouse Threat|newspaper=The New York Times|accessdate=20 January 2015}}
76. ^{{cite journal|title=Land Clearing and the Biofuel Carbon Debt|author=Joseph Fargione|doi=10.1126/science.1152747|pmid=18258862|volume=319|issue=5867|journal=Science|pages=1235–1238|date=2008-02-29}}
77. ^¹{{cite web|url=http://www1.umn.edu/umnnews/Feature_Stories/Ethanol_fuel_presents_a_cornundrum.html|archiveurl=https://web.archive.org/web/20070922221657/http://www1.umn.edu/umnnews/Feature_Stories/Ethanol_fuel_presents_a_cornundrum.html|archivedate=2007-09-22|title=Ethanol fuel presents a corn-undrum|author=D. Morrison|date=18 September 2006|publisher=University of Minnesota|accessdate=14 January 2008}}
78. ^{{cite news|url=http://news.bbc.co.uk/2/hi/americas/6718155.stm|title=Lula calls for ethanol investment|date=4 June 2007|publisher=BBC|accessdate=14 January 2008}}
79. ^{{cite news|url=http://www.msnbc.msn.com/id/17500316/|title=Brazil's ethanol push could eat away at Amazon|date=7 March 2007|agency=Associated Press|accessdate=14 January 2008}}
80. ^Kononova, M. M. Soil Organic Matter, Its Nature, Its role in Soil Formation and in Soil Fertility, 1961
81. ^{{cite web|url=http://actetsme.info/cms/index.php?option=com_content&task=view&id=178&Itemid=2|archiveurl=https://web.archive.org/web/20080329113658/http://actetsme.info/cms/index.php?option=com_content&task=view&id=178&Itemid=2|archivedate=29 March 2008|title=Biofuels: An advisable strategy?|author=D. Russi|date=7 March 2007}}
82. ^Greater Transportation Energy and GHG Offsets from Bioelectricity Than EthanolCampbell, et al.Science 22 May 2009: 1055–1057.DOI:10.1126/science.1168885
83. ^Block, Ben, "Study: biofuels more efficient as electricity source. (EYE ON EARTH)(Brief article)" World Watch 22.
84. ^Hill, Jason, Stephen Polasky, Erik Nelson, David Tilman, Hong Huo, Lindsay Ludwig, James Neumann, Haochi Zheng, and Diego Bonta. "Climate change and health costs of air emissions from biofuels and gasoline. (SUSTAINABILITY SCIENCE)(Author abstract)." Proceedings of the National Academy of Sciences of the United States of America 106.6 (10 February 2009): 2077(6). Expanded Academic ASAP. Gale. BENTLEY UPPER SCHOOL LIBRARY (BAISL). 6 October 2009
85. ^¹{{cite web|url=http://www.wilsoncenter.org/topics/pubs/Brazil_SR_e3.pdf |title=Brazil Institute Special Report: The Global Dynamics of Biofuels |author1=D. Budny |author2=P. Sotero |publisher=Brazil Institute of the Woodrow Wilson Center (updated to Jan 2011) |date=April 2007 |accessdate=3 May 2008 |deadurl=yes |archiveurl=https://web.archive.org/web/20080528051442/http://www.wilsoncenter.org/topics/pubs/Brazil_SR_e3.pdf |archivedate=28 May 2008 |df=dmy }}
86. ^¹{{cite web|url=http://veja.abril.com.br/300408/p_058.shtml |title=Ele é o falso vilão |author=J. Duailibi |publisher=Veja Magazine |language=Portuguese |date=27 April 2008 |accessdate=3 May 2008 |deadurl=yes |archiveurl=https://web.archive.org/web/20080506103110/http://veja.abril.com.br/300408/p_058.shtml |archivedate=6 May 2008 |df=dmy }}
87. ^¹{{cite web |url=http://revistaepoca.globo.com/Revista/Epoca/0,,EMI5865-15273.html |title=Por que a cana é melhor que o milho |work=Época Magazine |author=M. H. Tachinardi |date=13 June 2008 |language=Portuguese |accessdate=6 August 2008 |deadurl=yes |archiveurl=https://web.archive.org/web/20080707090818/http://revistaepoca.globo.com/Revista/Epoca/0%2C%2CEMI5865-15273.html |archivedate=7 July 2008 |df=dmy }} Print edition pp. 73
88. ^{{cite web|url=http://www.iwmi.cgiar.org/EWMA/files/papers/Paper%20for%20Bioenergy%20and%20water-BelumReddy.pdf|title=Sweet sorghum: A Water Saving BioEnergy Crop|author= Belum V S Reddy|first2=A Ashok |last2=Kumar|first3=S|last3=Ramesh|publisher=International Crops Research Institute for the SemiArid Tropics|accessdate=14 January 2008}}
89. ^{{cite web|url=http://www.bic.searca.org/news/2006/oct/phi/25.html|title=RP INVESTOR TO PUT UP PIONEERING SWEET SORGHUM ETHANOL PLANT|date=25 October 2006|publisher=Manila Bulletin|accessdate=14 January 2008|deadurl=yes|archiveurl=https://web.archive.org/web/20080212021333/http://www.bic.searca.org/news/2006/oct/phi/25.html|archivedate=12 February 2008|df=dmy-all}}
90. ^{{cite web|url=http://www.hort.purdue.edu/newcrop/proceedings1993/v2-394.html|title=Sweet Sorghum for a Piedmont Ethanol Industry|author1=G. C. Rains |author2=J. S. Cundiff |author3=G. E. Welbaum |date=12 September 1997|accessdate=14 January 2008}}
91. ^{{cite web|url=http://www.icrisat.org/Media/2004/media13.htm|title=ICRISAT develops sweet sorghum for ethanol production|date=12 August 2004|accessdate=14 January 2008 |archiveurl = https://web.archive.org/web/20071215014630/http://www.icrisat.org/Media/2004/media13.htm |archivedate = 15 December 2007}}
92. ^{{cite web |url=http://ethanol.org/pdf/contentmgmt/Energy_Security_Issue_Brief.pdf |archiveurl=https://www.webcitation.org/678jvRqVo?url=http://ethanol.org/pdf/contentmgmt/Energy_Security_Issue_Brief.pdf |archivedate=23 April 2012 |title=Energy Security |publisher=Ethanol.org |accessdate=27 August 2011 |deadurl=yes |df=dmy }}
93. ^{{Cite book|author=M. Turon|title=Ethanol as Fuel: An Environmental and Economic Analysis|date=25 November 1998|publisher=U.C. Berkeley, Chemical Engineering|url=http://www.turon.com/papers/ethanol.htm}}
94. ^{{cite web |url=http://www.ethanol.org/pdf/contentmgmt/Science_Journal_January_2006.pdf |archiveurl=https://www.webcitation.org/678jvRFKm?url=http://www.ethanol.org/pdf/contentmgmt/Science_Journal_January_2006.pdf |archivedate=23 April 2012 |title=Ethanol Can Contribute to Energy and Environmental Goals |publisher=Ethanol.org |accessdate=27 August 2011 |deadurl=yes |df=dmy }}
95. ^{{cite web|url=http://www.eia.doe.gov/neic/brochure/infocard01.htm|title=Energy INFOcard |publisher=Eia.doe.gov |accessdate=27 August 2011}}
96. ^{{cite web|url=http://www.renewableenergyworld.com/rea/news/infocus/story?id=52564 |title=Ethanol Lowers Gas Prices 29–40 Cents Per Gallon |publisher=Renewableenergyworld.com |accessdate=27 August 2011}}
97. ^{{cite web|url=http://www.motor.com/article.asp?article_ID=1064|title=Texas Students Win National Auto Repair Crown|publisher=Motor.com|accessdate=20 January 2015}}
98. ^{{cite web|url=http://usatoday30.usatoday.com/sports/motor/2008-01-15-corvette-e85_N.htm|title=ALMS Corvettes going green with E85 fuel in 2008 - USATODAY.com|publisher=Usatoday30.usatoday.com|accessdate=20 January 2015}}
99. ^{{cite web|url=http://msn.foxsports.com/nascar/story/NASCAR-expected-to-make-move-to-E15-fuel-blend-for-2011-10150|title=NASCAR|author=Fox Sports|work=FOX Sports|accessdate=20 January 2015}}{{dead link|date=September 2017 |bot=InternetArchiveBot |fix-attempted=yes }}
100. ^{{cite web|url=http://www.space.com/businesstechnology/rocket-racing-tulsa-demonstration-100426.html|title=Rocket Racing League Unveils New Flying Hot Rod|work=Space.com|accessdate=20 January 2015}}
101. ^"Impact of Improved Stoves and Fuels on IAP", CEIHD Center for Entrepreneurship in International Health and Development. Retrieved 30 May 2010.
102. ^{{cite web|author=Jim Lane |url=http://www.biofuelsdigest.com/bdigest/2013/08/01/ineos-bio-produces-cellulosic-ethanol-from-waste-at-commercial-scale-print-friendly/ |title=INEOS Bio produces cellulosic ethanol from waste, at commercial scale – print-friendly |publisher=Biofuels Digest |date=2013-08-01 |accessdate=2014-06-15}}
103. ^{{cite web|url=http://www.azom.com/news.aspx?NewsID=24508 |title=Ethanol production using genetically engineered bacterium |publisher=Azom.com |date=2010-09-23 |accessdate=2012-04-23}}
104. ^{{cite news|url=http://www.ens-newswire.com/ens/apr2007/2007-04-12-02.asp|title=Air Pollution Rules Relaxed for U.S. Ethanol Producers|date=April 12, 2007|publisher=Environmental News Service|accessdate=2009-06-26}}
105. ^{{Cite web|url=https://www.ornl.gov/news/nano-spike-catalysts-convert-carbon-dioxide-directly-ethanol|title=Nano-spike catalysts convert carbon dioxide directly into ethanol {{!}} ORNL|website=www.ornl.gov|access-date=2016-11-11}}