alcohol fuel

Image:Ethanol as a fuel.jpg

{{main|Methanol fuel|Ethanol fuel}}

Methanol and ethanol can both be derived from fossil fuels, biomass, or from carbon dioxide and water. Ethanol has most commonly been produced through fermentation of sugars, and methanol has most commonly been produced from synthesis gas, but there are more modern ways to obtain these fuels. Enzymes can be used instead of fermentation. Methanol is the simpler molecule, and ethanol can be made from methanol. Methanol can be produced industrially from nearly any biomass, including animal waste, or from carbon dioxide and water or steam by first converting the biomass to synthesis gas in a gasifier. It can also be produced in a laboratory using electrolysis or enzymes.

ENZYMATIC CONVERSION OF CARBON

DIOXIDE TO METHANOL {{cite web |url=http://www.anl.gov/PCS/acsfuel/preprint%20archive/Files/47_1_Orlando_03-02_0072.pdf |title=Archived copy |access-date=2010-11-28 |url-status=dead |archive-url=https://web.archive.org/web/20120315121755/http://www.anl.gov/PCS/acsfuel/preprint%20archive/Files/47_1_Orlando_03-02_0072.pdf |archive-date=2012-03-15 }}

As a fuel, methanol and ethanol both have advantages and disadvantages over fuels such as petrol (gasoline) and diesel fuel. In spark ignition engines, both alcohols can run at much higher exhaust gas recirculation rates and with higher compression ratios. Both alcohols have a high octane rating, with ethanol at 109 RON (Research Octane Number), 90 MON (Motor Octane Number), (which equates to 99.5 AKI) and methanol at 109 RON, 89 MON (which equates to 99 AKI).Owen, K., Coley., C.S. Weaver, "Automotive Fuels Reference Book", SAE International, {{ISBN|978-1-56091-589-8}} Note that AKI refers to 'Anti-Knock Index' which averages the RON and MON ratings (RON+MON)/2, and is used on U.S. gas station pumps. Ordinary European petrol is typically 95 RON, 85 MON, equal to 90 AKI. As a compression ignition engine fuel, both alcohols create very few particulates, but their low cetane number means that an ignition improver like glycol must be mixed into the fuel at approx. 5%.

When used in spark ignition engines alcohols have the potential to reduce NOx, CO, HC and particulates. A test with E85 fueled Chevrolet Luminas showed that NMHCNon-Methane HydroCarbons {{cite web |url=http://www.atmosphere.mpg.de/enid/EN__Compounds/NMHC_5rg.html |title=NMHC |access-date=2010-11-27 |url-status=dead |archive-url=https://web.archive.org/web/20110727031815/http://www.atmosphere.mpg.de/enid/EN__Compounds/NMHC_5rg.html |archive-date=2011-07-27 }} went down by 20-22%, NOx by 25-32% and CO by 12-24% compared to reformulated gasoline.Kelly, K.J., Bailey, B.K., Coburn, T.C., Clark, W., Lissiuk, P. "Federal Test Procedure Emissions Test Results from Ethanol Variable-Fuel Vehicle Chevrolet Luminas", SAE Technical Paper 961092 Toxic emissions of benzene and 1,3-butadiene also decreased while aldehyde emissions increased, acetaldehyde in particular.

Tailpipe emissions of CO₂ also decrease due to the lower carbon-to-hydrogen ratio of these alcohols, and improved engine efficiency.

Methanol and ethanol fuels contain soluble and insoluble contaminants.Brinkman, N., Halsall, R., Jorgensen, S.W., & Kirwan, J.E., "The Development Of Improved Fuel Specifications for Methanol (M85) and Ethanol (Ed85), SAE Technical Paper 940764 Halide ions, which are soluble contaminants, such as chloride ions, have a large effect on the corrosivity of alcohol fuels. Halide ions increase corrosion in two ways: they chemically attack passivating oxide films on several metals causing pitting corrosion, and they increase the conductivity of the fuel. Increased electrical conductivity promotes electrical, galvanic and ordinary corrosion in the fuel system. Soluble contaminants such as aluminum hydroxide, itself a product of corrosion by halide ions, clog the fuel system over time.

To prevent corrosion the fuel system must be made of suitable materials, electrical wires must be properly insulated and the fuel level sensor must be of pulse and hold type magneto resistive or other similar non-contact type. In addition, high quality alcohol should have a low concentration of contaminants and have a suitable corrosion inhibitor added. Scientific evidence reveals that water is an inhibitor for corrosion by ethanol.{{cite book |chapter-url=http://papers.sae.org/2005-01-3708 |chapter=Effect of Alcohol Fuels on Fuel-Line Materials of Gasoline Vehicles |publisher=SAE |doi=10.4271/2005-01-3708 |url-status=live |archive-url=https://web.archive.org/web/20131204192849/http://papers.sae.org/2005-01-3708/ |archive-date=2013-12-04 |title=SAE Technical Paper Series |year=2005 |last1=Kameoka |first1=Atsushi |last2=Nagai |first2=Keiichi |last3=Sugiyama |first3=Gen |last4=Seko |first4=Toshiyuki |volume=1 }}

The experiments are done with E50, which is more aggressive and speeds up the corrosion effect. It is very clear that by increasing the amount of water in fuel ethanol one can reduce corrosion. At 2% or 20,000 ppm water in the ethanol fuel the corrosion stopped. In line with the observations in Japan, hydrous ethanol is known to be less corrosive than anhydrous ethanol. The reaction mechanism is 3 EtOH + Al -> Al(OEt)₃ + {{frac|3|2|}} H₂ at lower-mid blends. When enough water is present in the fuel, aluminum will react preferably with water to produce Al₂O₃, repairing the protective aluminum oxide layer. The aluminum alkoxide does not make a tight oxide layer; water is essential to repair the holes in the oxide layer.

Methanol and ethanol are incompatible with some polymers. The alcohol reacts with the polymers causing swelling, and over time oxygen breaks down the carbon-carbon bonds in the polymer causing a reduction in tensile strength. For the past few decades though, most cars have been designed to tolerate up to 10% ethanol (E10) without problem. This includes both fuel system compatibility and lambda compensation{{Clarify|date=May 2009}} of fuel delivery with fuel injection engines featuring closed loop lambda control. In some engines ethanol may degrade some compositions of plastic or rubber fuel delivery components designed for conventional petrol, and also be unable to lambda compensate the fuel properly. {{Citation needed|date=August 2008}}

"FlexFuel" vehicles have upgraded fuel system and engine components which are designed for long life using E85 or M85, and the ECU can adapt to any fuel blend between gasoline and E85 or M85. Typical upgrades include modifications to: fuel tanks, fuel tank electrical wiring, fuel pumps, fuel filters, fuel lines, filler tubes, fuel level sensors, fuel injectors, seals, fuel rails, fuel pressure regulators, valve seats and inlet valves. "Total Flex" autos destined for the Brazilian market can use E100 (100% ethanol).{{Citation needed|date=October 2010}}

One liter of ethanol releases 21.1 MJ in combustion, a liter of methanol 15.8 MJ and a liter of gasoline approximately 32.6 MJ. In other words, for the same energy content as one liter or one gallon of gasoline, one needs 1.6 liters/gallons of ethanol and 2.1 liters/gallons of methanol. The raw energy-per-volume numbers produce misleading fuel consumption numbers, however, because alcohol-fueled engines can be made substantially more energy-efficient. A larger percentage of the energy released by combustion of a liter of alcohol fuel can be converted to useful work. This difference in efficiency can partially or totally balance out the energy density difference,{{Citation needed|date=October 2012}} depending on the particular engines being compared.

Methanol fuel has been proposed as a future biofuel, often as an alternative to the hydrogen economy. Methanol has a long history as a racing fuel. Early Grand Prix Racing used blended mixtures as well as pure methanol. The fuel was primarily used in North America after the war. {{Clarify|date=May 2009}} However, methanol for racing purposes has largely been based on methanol produced from syngas derived from natural gas and therefore this methanol would not be considered a biofuel. Methanol is a possible biofuel, however, when the syngas is derived from biomass.

In theory, methanol can also be produced from sustainably sourced biomass and ultimately carbon dioxide, and by hydrogen electrolysis using nuclear power, geothermal power or some other renewable energy source (see Carbon Recycling International). Compared to bioethanol, the primary advantage of methanol biofuel is its much greater well-to-wheel efficiency. This is particularly relevant in temperate climates where fertilizers are needed to grow sugar or starch crops to make ethanol, whereas methanol can be produced from unfertilized lignocellulose (woody) biomass.

Ethanol is already being used extensively as a fuel additive, and the use of ethanol fuel alone or as part of a mix with gasoline is increasing. Compared to methanol its primary advantage is that it is less corrosive and non-toxic, although the fuel will produce some toxic exhaust emissions. Since 2007, IndyCar has used ethanol as its exclusive fuel, after 40 years of using methanol.{{cite web|url=http://www.indycar.com/tech/ethanol.php |title=Tech: ethanol |publisher=Indycar.com |access-date=22 May 2007 |url-status=dead |archive-url=https://web.archive.org/web/20070708141152/http://www.indycar.com/tech/ethanol.php |archive-date=8 July 2007 }} Since September 2007 petrol stations in NSW, Australia have been mandated to supply all their petrol with 2% ethanol content.{{cite news|url=http://www.smh.com.au/news/NATIONAL/NSW-to-mandate-ethanol-in-petrol/2007/05/11/1178390531377.html |title=NSW to mandate ethanol in petrol |publisher=Sydney Morning Herald |access-date=5 October 2007 |date=2007-05-11 |archive-url=https://web.archive.org/web/20071021064409/http://www.smh.com.au/news/NATIONAL/NSW-to-mandate-ethanol-in-petrol/2007/05/11/1178390531377.html |archive-date=21 October 2007 |url-status=live }}

{{Main|Butanol fuel}}

Propanol and butanol are considerably less toxic and less volatile than methanol. In particular, butanol has a high flash point of 35 °C, which is a benefit for fire safety, but may be a difficulty for starting engines in cold weather. The concept of flash point is, however, not directly applicable to engines as the compression of the air in the cylinder means that the temperature is several hundred degrees Celsius before ignition takes place.

The fermentation processes to produce propanol and butanol from cellulose are fairly tricky to execute, and the Weizmann organism (Clostridium acetobutylicum) currently used to perform these conversions produces an extremely unpleasant smell; this must be taken into consideration when designing and locating a fermentation plant. This organism also dies when the butanol content of whatever it is fermenting rises to 2%.{{Cite journal|date=2018-11-01|title=Enhanced butanol production by optimization of medium parameters using Clostridium acetobutylicum YM1|journal=Saudi Journal of Biological Sciences|language=en|volume=25|issue=7|pages=1308–1321|doi=10.1016/j.sjbs.2016.02.017|issn=1319-562X|pmc=6251989|last1=Al-Shorgani |first1=Najeeb Kaid Nasser |last2=Shukor |first2=Hafiza |last3=Abdeshahian |first3=Peyman |last4=Kalil |first4=Mohd Sahaid |last5=Yusoff |first5=Wan Mohtar Wan |last6=Hamid |first6=Aidil Abdul |pmid=30505175 |bibcode=2018SJBS...25.1308A }} For comparison, yeast dies when the ethanol content of its feedstock hits 14%. Specialized strains can tolerate even greater ethanol concentrations - so-called turbo yeast can withstand up to 16% ethanol.{{cite web|url=http://running_on_alcohol.tripod.com/|title=Make your own Fuel|publisher=Tripod.com|access-date=22 May 2007|url-status=live|archive-url=https://web.archive.org/web/20070929111546/http://running_on_alcohol.tripod.com/|archive-date=29 September 2007}} However, if ordinary Saccharomyces yeast can be modified to improve its ethanol resistance, scientists may yet one day produce a strain of the Weizmann organism with a butanol resistance higher than the natural boundary of 7%. This would be useful because butanol has a higher combustion energy density than ethanol, and because waste fibre left over from sugar crops used to make ethanol could be made into butanol, raising the alcohol yield of fuel crops without requiring more crops to be planted.

Despite these drawbacks, DuPont and BP have recently announced that they are jointly to build a small scale butanol fuel demonstration plant{{cite web|url=http://www.bp.com/genericarticle.do?categoryId=2012968&contentId=7034350 |title=BP, ABF and DuPont Unveil $400 Million Investment in UK Biofuels |publisher=BP |access-date=3 August 2007 |url-status=dead |archive-url=https://web.archive.org/web/20070824022254/http://www.bp.com/genericarticle.do?categoryId=2012968&contentId=7034350 |archive-date=24 August 2007 }} alongside the large bioethanol plant they are jointly developing with Associated British Foods.

The company Energy Environment International developed a method for producing butanol from biomass, which involves the use of two separate micro-organisms in sequence to minimize production of acetone and ethanol byproducts.{{cite web|url=http://www.butanol.com |title=Butanol Works in your Car Today |publisher=Environmental Energy, inc |access-date=22 May 2007 |archive-url=https://web.archive.org/web/20070529123858/http://www.butanol.com/ |archive-date=29 May 2007 |url-status=live }}

The Swiss company Butalco GmbH uses a special technology to modify yeasts in order to produce butanol instead of ethanol. Yeasts as production organisms for butanol have decisive advantages compared to bacteria.[http://www.butalco.com Home] {{webarchive|url=https://web.archive.org/web/20071101094808/http://www.butalco.com/ |date=2007-11-01 }}.

Butanol combustion: C₄H₉OH + 6O₂ → 4CO₂ + 5H₂O + heat

Propanol combustion: 2C₃H₇OH + 9O₂ → 6 CO₂ + 8H₂O + heat

The 3-carbon alcohol, propanol (C₃H₇OH), is not often used as a direct fuel source for petrol engines (unlike ethanol, methanol and butanol), with most being directed into use as a solvent. However, it is used as a source of hydrogen in some types of fuel cell; it can generate a higher voltage than methanol, which is the fuel of choice for most alcohol-based fuel cells. However, since propanol is harder to produce than methanol (biologically or from oil), methanol-utilizing fuel cells are preferred over those that utilize propanol.

{{Main|Ethanol fuel in Brazil}}

File:Historical trend ethanol and flex veh in Brazil 1979 2008.png, and gasoline vehicles from 1979 to 2017.{{Cite web |url=http://www.virapagina.com.br/anfavea2018/59/#zoom=z |title=Anuário da Indústria Automobilística Brasileira 2018, ANFAVEA |access-date=2018-12-16 |archive-date=2018-12-16 |archive-url=https://web.archive.org/web/20181216062941/http://www.virapagina.com.br/anfavea2018/59/#zoom=z |url-status=dead }}]]

Brazil was until recently the largest producer of alcohol fuel in the world, typically fermenting ethanol from sugarcane.

The country produces a total of 18 billion litres (4.8 billion gallons) annually, of which 3.5 billion liters are exported, 2 billion of them to the U.S.{{cite news|url=http://br.invertia.com/noticias/noticia.aspx?idNoticia=200703051055_ABR_30409713 |archive-url=https://web.archive.org/web/20070307074624/http://br.invertia.com/noticias/noticia.aspx?idNoticia=200703051055_ABR_30409713 |url-status=dead |archive-date=2007-03-07 |title=Lula diz que taxa dos EUA sobre etanol não tem sentido |publisher=Invertia |date=2007-03-05 |access-date=2007-05-22 |language=pt }} Alcohol cars debuted in the Brazilian market in 1979 and became quite popular because of a heavy subsidy, but in the 1980s prices rose and gasoline regained the leading market share.{{cite web |url=http://g1.globo.com/Noticias/Carros/0,,MUL1234087-9658,00.html |title=Indústria comemora 30 anos do 1º carro a álcool no país (Portuguese) |publisher=globo.com |date=2009-09-19 |access-date=2013-02-20}}

However, from 2003 on, alcohol has rapidly increased its market share once again because of new technologies involving flexible-fuel engines,{{cite news|url=http://news.bbc.co.uk/1/hi/business/4581955.stm|title=The rise, fall and rise of Brazil's biofuel|work=BBC News|date=2006-01-24|access-date=2007-05-22|url-status=live|archive-url=https://web.archive.org/web/20070807211736/http://news.bbc.co.uk/1/hi/business/4581955.stm|archive-date=2007-08-07}} called "Flex" or "Total Flex" by all major car manufacturers (Volkswagen, General Motors, Fiat, etc.). "Flex" engines work with gasoline, alcohol or any mixture of both fuels. As of May 2009, more than 88% of new vehicles sold in Brazil are flex fuel.{{cite news|url=http://economia.terra.com.br/noticias/noticia.aspx?idNoticia=200906041737_RTR_1244137077nN04224621 |publisher=Invertia |date=2009-06-04 |access-date=2009-12-16 |title=de carros flex sobe em maio para 210,4 mil unidades |language=pt |url-status=dead |archive-url=https://web.archive.org/web/20110706154732/http://economia.terra.com.br/noticias/noticia.aspx?idNoticia=200906041737_RTR_1244137077nN04224621 |archive-date=2011-07-06 }}

Because of the Brazilian leading production and technology, many countries became very interested in importing alcohol fuel and adopting the "Flex" vehicle concept. On March 7 of 2007, US president George W. Bush visited the city of São Paulo to sign agreements with Brazilian president Luiz Inácio Lula da Silva on importing alcohol and its technology as an alternative fuel.{{cite web|url=http://www.foodfirst.org/node/1654 |title=Women in Brazil Protest Bush's Visit: The poor refuse to grow fuel for the rich |publisher=Food First/Institute for Food and Development Policy |date=2007-03-07 |access-date=2011-12-04 |url-status=dead |archive-url=https://web.archive.org/web/20110927021642/http://www.foodfirst.org/node/1654 |archive-date=2011-09-27 }}

{{Main|Bioenergy in China}}

As early as 1935, China has made alcohol fuel powered cars.{{cite web |url=http://www.cqzx.gov.cn/Uploadfiles/szb/20100309-110253.pdf |title=Archived copy |access-date=2014-05-04 |url-status=dead |archive-url=https://web.archive.org/web/20140504140109/http://www.cqzx.gov.cn/Uploadfiles/szb/20100309-110253.pdf |archive-date=2014-05-04 }} 各种动力的抗战牌汽车 China has reported with a 70% methanol use to conventional gasoline an independence from crude oil.

The National Committee of Planning and Action Coordination for Clean Automobile had listed key technologies related to alcohol/ether fuel and accelerated industrialization in its main agenda. Alcohol fuels had become part of five main alternative fuels, two of which were alcohols: methanol and ethanol.{{cite web|url=http://www.eri.ucr.edu/ISAFXVCD/ISAFXVPP/AlEFC.pdf |title=Alcohol Ether Fuel in China |publisher=University of California Riverside Environmental Research Institute |date=13 Nov 2005 |access-date=2011-12-04 |url-status=dead |archive-url=https://web.archive.org/web/20111009051748/http://www.eri.ucr.edu/ISAFXVCD/ISAFXVPP/AlEFC.pdf |archive-date=2011-10-09 }}

:See E85 in the United States

The United States at the end of 2007 was producing 26.9 billion litres (7 billion gallons) per year.[http://www.ethanol.org/pdf/contentmgmt/2007_Ethanol_Fact_Book.pdf Ethanol Fact Book] {{webarchive|url=https://web.archive.org/web/20080528051420/http://www.ethanol.org/pdf/contentmgmt/2007_Ethanol_Fact_Book.pdf |date=2008-05-28 }} E10 or Gasohol is commonly marketed in Delaware and E85 is found in many states, particularly in the Midwest where ethanol from corn is produced locally.

Many states and municipalities have mandated that all gasoline fuel be blended with 10 percent alcohol (usually ethanol) during some or all of the year. This is to reduce pollution and allows these areas to comply with federal pollution limits. Because alcohol is partially oxygenated, it produces less overall pollution, including ozone. In some areas (California in particular) the regulations may also require other formulations or added chemicals that reduce pollution, but add complexity to the fuel distribution and increase the cost of the fuel.

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{{Main|:ja:ガイアックス_(燃料)|:ja:アルコール燃料}}

The first alcohol fuel in Japan began with GAIAX in 1999. GAIAX was developed in South Korea, and imported by Japan. The principal ingredient was methanol.

Because GAIAX was not gasoline, it was a tax-free object of the gas tax of Japan. However, as a result, the use of GAIAX came to be considered an act of smuggling in Japan by the government and the petroleum industry. Retailing of GAIAX was done to avoid the tax evasion criticism by independently paying the diesel fuel tax in the legal system regulations.

Accidental vehicle fires where GAIAX was being refueled began to be reported in around 2000 when the tax evasion discussion had almost ended. The car industry in Japan criticized GAIAX, saying that "fires broke out because high density alcohol had corroded the fuel pipes". GAIAX was named a "high density alcohol fuel", and a campaign was executed to exclude it from the market long term. Finally, the Ministry of Economy, Trade and Industry also joined this campaign.[http://www.enecho.meti.go.jp/topics/nennryouhp/index.html 「高濃度アルコール含有燃料は、車の安全にNO！環境にNO！」] {{webarchive|url=https://web.archive.org/web/20100518085223/http://www.enecho.meti.go.jp/topics/nennryouhp/index.html |date=2010-05-18 }} 経済産業省・資源エネルギー庁HP

The gasoline quality method was revised under the pretext of safety concerns in 2003. This prohibited the manufacturing and sale of "High density alcohol fuel", and added a substantial GAIAX sales ban. By revising the law, fuel manufacturers are prohibited from adding 3% or more alcohol to gasoline. This revision to the law is grounds not to be able to sell alcohol fuel greater than E3 in Japan.

The petroleum industry in Japan is now proceeding with research and development of an original alcohol fuel that differs from GAIAX. However, the commercial manufacture and sale of any new fuel may be barred by existing laws that currently exclude GAIAX from the market. Moreover, the strong aversion by the Japanese consumer to a high density alcohol fuel of any type may prevent commercial success of any new fuel.

{{Portal|Energy|Renewable energy}}

{{div col|colwidth=30em}}

• Anaerobic digestion
• Bioconversion of biomass to mixed alcohol fuels
• Bioethanol
• Biogas
• Butanol
• Direct biofuel
• E85
• Ecalene
• Energy development
• Ethanol fuel
• Hydrogen fuel
• Methanol fuel
• Propanol
• Timeline of alcohol fuel

{{div col end}}

{{Reflist|2}}

{{Commonscat|Alcohol fuels}}

• [https://web.archive.org/web/20080516004927/http://econ.worldbank.org/WBSITE/EXTERNAL/EXTDEC/EXTRESEARCH/EXTWDRS/EXTWDR2008/0%2C%2CcontentMDK%3A21501336~pagePK%3A64167689~piPK%3A64167673~theSitePK%3A2795143%2C00.html World Bank, Biofuels: The Promise and the Risks. World Development Report 2008: Agriculture for Development]
• [http://www.eere.energy.gov/afdc/fuels/emerging_biobutanol.html Biobutanol] by EERE.
• http://www.greencarcongress.com/biobutanol/index.html
• https://web.archive.org/web/20080528051420/http://www.ethanol.org/pdf/contentmgmt/2007_Ethanol_Fact_Book.pdf

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{{DEFAULTSORT:Alcohol Fuel}}

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