Diesel or diesel fuel (IPA: /ˈdiːzəl/) in general is any fuel used in diesel engines. Production costs are 25-35% less than that of regular gasoline. The most common is a specific fractional distillate of petroleum fuel oil, but alternatives that are not derived from petroleum, such as biodiesel, biomass to liquid (BTL) or gas to liquid (GTL) diesel, are increasingly being developed and adopted. To distinguish these types, petroleum-derived diesel is increasingly called petrodiesel. Ultra-low sulfur diesel (ULSD) is a term used to describe a standard for defining diesel fuel with substantially lowered sulfur contents. As of 2007, almost every diesel fuel available in America and Europe are ULSD type.
Diesel engines are a type of internal combustion engine. Rudolf Diesel originally designed the diesel engine to use vegetable oils as a fuel in order to help support agrarian society and to enable independent craftsmen and artisans to compete with large industry.
The density of petroleum diesel is about 850 grams per litre whereas petrol (gasoline) has a density of about 720 g/L, about 15% less. When burnt, diesel typically releases about 138,700 (Expression error: Missing operand for *. ) per US gallon, whereas gasoline releases 125,000 (Expression error: Missing operand for *. ) per US gallon, about 11% less. Diesel is generally simpler to refine from petroleum than gasoline. The price of diesel traditionally rises during colder months as demand for heating oil rises, which is refined in much the same way. Due to its higher level of pollutants, diesel must undergo additional filtration which contributes to a sometimes higher cost. In many parts of the United States and throughout the UK, diesel may be higher priced than petrol. Reasons for higher priced diesel include the shutdown of some refineries in the Gulf of Mexico, diversion of mass refining capacity to gasoline production, and a recent transfer to ultra-low sulfur diesel (ULSD), which causes infrastructural complications.
Diesel-powered cars generally have a better fuel economy than equivalent gasoline engines and produce less greenhouse gas pollution. Their greater economy is due to the higher energy per-litre content of diesel fuel and the intrinsic efficiency of the diesel engine. While petrodiesel's 15% higher density results in 15% higher greenhouse gas emissions per litre compared to gasoline, the 20–40% better fuel economy achieved by modern diesel-engined automobiles offsets the higher-per-liter emissions of greenhouse gases, and produces 10-20 percent less GHG emissions than comparable gasoline vehicles. However, the EPA carbon footprint estimates do not include the carbon cost of vehicle manufacture, nor the carbon cost of filtering particulates, sulfates, and nitrates emissions. Biodiesel-powered diesel engines offer substantially improved emission reductions compared to petro-diesel or gasoline-powered engines, while retaining most of the fuel economy advantages over conventional gasoline-powered automobiles.
In the past, diesel fuel contained higher quantities of sulfur. European emission standards and preferential taxation have forced oil refineries to dramatically reduce the level of sulfur in diesel fuels. In the United States, more stringent emission standards have been adopted with the transition to ULSD starting in 2006 and becoming mandatory on June 1, 2010 (see also diesel exhaust). U.S. diesel fuel typically also has a lower cetane number (a measure of ignition quality) than European diesel, resulting in worse cold weather performance and some increase in emissions. This is one reason why U.S. drivers of large trucks have increasingly turned to biodiesel fuels with their generally higher cetane ratings.
High levels of sulfur in diesel are harmful for the environment because they prevent the use of catalytic diesel particulate filters to control diesel particulate emissions, as well as more advanced technologies, such as nitrogen oxide (NOx) adsorbers (still under development), to reduce emissions. However, the process for lowering sulfur also reduces the lubricity of the fuel, meaning that additives must be put into the fuel to help lubricate engines. Biodiesel and biodiesel/petrodiesel blends, with their higher lubricity levels, are increasingly being utilized as an alternative.
The U.S. annual consumption of diesel fuel in 2006 was about 190 billion litres (42 billion imperial gallons or 50 billion US gallons). 
Petroleum-derived diesel is composed of about 75% saturated hydrocarbons (primarily paraffins including n, iso, and cycloparaffins), and 25% aromatic hydrocarbons (including naphthalenes and alkylbenzenes). The average chemical formula for common diesel fuel is C12H23, ranging from approx. C10H20 to C15H28
Algae, microbes, and water
There has been much discussion and misinformation about algae in diesel fuel. Algae require sunlight to live and grow. As there is no sunlight in a closed fuel tank, no algae can survive there. However, some microbes can survive there, and can feed on the diesel fuel.
These microbes form a colony that lives at the fuel/water interface. They grow quite rapidly in warmer temperatures. They can even grow in cold weather when fuel tank heaters are installed. Parts of the colony can break off and clog the fuel lines and fuel filters.
It is possible to either kill this growth with a biocide treatment, or eliminate the water, a necessary component of microbial life. There are a number of biocides on the market, which must be handled very carefully. If a biocide is used, it must be added every time a tank is refilled until the problem is fully resolved.
Biocides attack the cell wall of microbes resulting in lysis, the death of a cell by bursting. The dead cells then gather on the bottom of the fuel tanks and form a sludge, filter clogging will continue after biocide treatment until the sludge has abated.
Given the right conditions microbes will repopulate the tanks and re-treatment with biocides will then be necessary. With repetitive biocide treatments microbes can then form resistance to a particular brand. Trying another brand may resolve this.
Petrodiesel spilled on a road will stay there until washed away by sufficiently heavy rain, whereas gasoline will quickly evaporate. Diesel spills severely reduce tire grip and have been implicated in many accidents. They are especially dangerous for two-wheeled vehicles.
Wood, hemp, straw, corn, garbage, food scraps, and sewage-sludge may be dried and gasified to synthesis gas. After purification the Fischer-Tropsch process is used to produce synthetic diesel. This means that synthetic diesel oil may be one route to biomass based diesel oil. Such processes are often called Biomass-To-Liquids or BTL.
Synthetic diesel may also be produced out of natural gas in the Gas-to-liquid (GTL) process or out of coal in the Coal-to-liquid (CTL) process. Such synthetic diesel has 30% less particulate emissions than conventional diesel (US- California).
Biodiesel can be obtained from vegetable oil (vegidiesel/vegifuel), or animal fats (bio-lipids), using transesterification. Biodiesel is a non-fossil fuel alternative to petrodiesel. It can also be mixed with petrodiesel in any amount in modern engines, though when first using it, the solvent properties of the fuel tend to dissolve accumulated deposits and can clog fuel filters. Biodiesel has a higher gel point than petrodiesel, but is comparable to diesel. This can be overcome by using a biodiesel/petrodiesel blend, or by installing a fuel heater, but this is only necessary during the colder months. A diesel-biodiesel mix results in lower emissions than either can achieve alone, except for NOx emissions. A small fraction of biodiesel can be used as an additive in low-sulfur formulations of diesel to increase the lubricity lost when the sulfur is removed. In the event of fuel spills, biodiesel is easily washed away with ordinary water and is nontoxic compared to other fuels.
Biodiesel can be produced using kits. Certain kits allow for processing of used vegetable oil that can be run through any conventional diesel motor with modifications. The modification needed is the replacement of fuel lines from the intake and motor and all affected rubber fittings in injection and feeding pumps a.s.o. This is because biodiesel is an effective solvent and will replace softeners within unsuitable rubber with itself over time. Synthetic gaskets for fittings and hoses prevent this.
Chemically, most biodiesel consists of alkyl (usually methyl) esters instead of the alkanes and aromatic hydrocarbons of petroleum derived diesel. However, biodiesel has combustion properties very similar to petrodiesel, including combustion energy and cetane ratings. Paraffin biodiesel also exists. Due to the purity of the source, it has a higher quality than petrodiesel.
The use of biodiesel blended diesel fuels in fractions up to 99% result in substantial emission reductions. Sulfur oxide and sulfate emissions, major components of acid rain, are essentially eliminated with pure biodiesel and substantially reduced using biodiesel blends with minor quantities of ULSD petrodiesel. Use of biodiesel also results in substantial reductions of unburned hydrocarbons, carbon monoxide, and particulate matter compared to either gasoline or petrodiesel. C02, or carbon monoxide emissions using biodiesel are substantially reduced, on the order of 50% compared to most petrodiesel fuels. The exhaust emissions of particulate matter from biodiesel have been found to be 30 percent lower than overall particulate matter emissions from petrodiesel. The exhaust emissions of total hydrocarbons (a contributing factor in the localized formation of smog and ozone) are up to 93 percent lower for biodiesel than diesel fuel. Biodiesel emissions of nitrogen oxides can sometimes increase slightly. However, biodiesel's complete lack of sulfur and sulfate emissions allows the use of NOx control technologies, such as AdBlue, that cannot be used with conventional diesel, allowing the management and control of nitrous oxide emissions.
Biodiesel also may reduce health risks associated with petroleum diesel. Biodiesel emissions showed decreased levels of PAH and nitrited PAH compounds which have been identified as potential cancer causing compounds. In recent testing, PAH compounds were reduced by 75 to 85 percent, with the exception of benzo(a)anthracene, which was reduced by roughly 50 percent. Targeted nPAH compounds were also reduced dramatically with biodiesel fuel, with 2-nitrofluorene and 1-nitropyrene reduced by 90 percent, and the rest of the nPAH compounds reduced to only trace levels.
The first diesel powered flight of a fixed wing aircraft took place on the evening of September 18, 1928, at the Packard Motor Company proving grounds, Utica, Michigan with Captain Lionel M. Woolson and Walter Lees at the controls (the first "official" test flight was taken the next morning). The engine was designed for Packard by Woolson and the aircraft was a Stinson SM1B, X7654. Later that year Charles Lindbergh flew the same aircraft. In 1929 it was flown 621 miles (999.402624 km) non-stop from Detroit to Langley, Virginia (near Washington, D.C.). This aircraft is presently owned by Greg Herrick and resides in the Golden Wings Flying Museum near Minneapolis, Minnesota. In 1931, Walter Lees and Fredrick Brossy set the nonstop flight record flying a Bellanca powered by a Packard diesel for 84h 32 m. The Hindenburg was powered by four 16 cylinder diesel engines, each with approximately 1,200 (Expression error: Missing operand for *. ) available in bursts, and 850 (Expression error: Missing operand for *. ) available for cruising. Modern diesel engines for propellor-driven aircraft are manufactured by Thielert Aircraft Engines and SMA. These engines are able to run on Jet A fuel, which is similar in composition to automotive diesel and cheaper and more plentiful than the 100 octane low-lead gasoline (avgas) used by the majority of the piston-engine aircraft fleet.
The most-produced aviation diesel engine in history so far has been the Junkers Jumo 205, which, along with its similar developments from the Junkers Motorenwerke, had approximately 1000 examples of the unique opposed piston, two-stroke design powerplant built in the 1930s leading into World War II in Germany.
The very first diesel-engine automobile trip (inside USA) was completed on January 6, 1930. The trip was from Indianapolis to New York City, a distance of nearly 800 miles (1300 km). This feat helped to prove the usefulness of the compression ignition engine.
In 1931, Dave Evans drove his Cummins Diesel Special to a nonstop finish in the Indianapolis 500, the first time a car had completed the race without a pit stop. That car and a later Cummins Diesel Special are on display at the Indianapolis Motor Speedway Hall of Fame Museum.
In the late 1970s Mercedes-Benz at Nardò drove a C111-III with a 5 cylinder diesel engine to several new records, including driving an average of 314 km/h (195 mph) for 12 hours and hitting a top speed of 325 km/h (201 mph).
With turbocharged diesel cars getting stronger in the 1990s, they were entered in touring car racing, and BMW even won the 24 Hours Nürburgring in 1998 with a 320d. After winning the 12 Hours of Sebring in 2006 with their diesel-powered R10 LMP, Audi won the 24 Hours of Le Mans, too. This is the first time a diesel-fueled vehicle has won at Le Mans against cars powered with regular fuel or other alternative fuel like methanol or bio-ethanol. Competitors like Porsche predicted this victory for Audi as current FIA and ACO regulations are seen as pro-diesel. French automaker Peugeot entered the diesel powered Peugeot 908 LMP in the 2007 24 Hours of Le Mans in response to the success of the Audi R10.
In an effort to further demonstrate the potential of diesel power, California-based Gale Banks Engineering designed, built and raced a Cummins-powered pickup at the Bonneville Salt Flats in October 2002. The truck set a top speed of 355 km/h (222 mph) and became the world’s fastest pickup, and almost equally notable, the truck drove to the race towing its own support trailer.
On 23 August 2006, the British-based earthmoving machine manufacturer JCB raced the specially designed JCB Dieselmax car at 563.4 km/h (350.1 mph). The driver was Andy Green. The car was powered by two modified JCB 444 diesel engines.
Poor quality, (high sulfur) diesel fuel has been used as a palladium extraction agent for the liquid-liquid extraction of this metal from nitric acid mixtures. This has been proposed as a means of separating the fission product palladium from PUREX raffinate which comes from used nuclear fuel. In this solvent extraction system the hydrocarbons of the diesel act as the diluent while the dialkyl sulfides act as the extractant. This extraction operates by a solvation mechanism. So far neither a pilot plant or full scale plant has been constructed to recover palladium, rhodium or ruthenium from nuclear wastes created by the use of nuclear fuel.
Diesel combustion exhaust is an important source of atmospheric soot and fine particles, which is a fraction of air pollution implicated in human heart and lung damage. Diesel exhaust also contains nanoparticles which have been found to damage the cardiovascular system in a mouse model. The study of nanotoxicology is still in its infancy, and the extent of health and societal effects caused by diesel combustion is unknown. Biodiesel and biodiesel blends result in greatly decreased pollution levels.
Diesel fuel is very similar to heating oil which is used in central heating. In Europe, the United States, and Canada, taxes on diesel fuel are higher than on heating oil due to the fuel tax, and in those areas, heating oil is marked with fuel dyes and trace chemicals to prevent and detect tax fraud. Similarly, "untaxed" diesel (sometimes called "off road diesel") is available in the United States, which is available for use primarily in agricultural applications such as fuel for tractors, recreational and utility vehicles or other non-commercial vehicles that do not use public roads. Additionally, this fuel may have sulphur levels that exceed the limits for road use using the newer 2007 standards. This untaxed diesel is dyed red for identification purposes, and should a person be found to be using this untaxed diesel fuel for a typically taxed purpose (such as "over-the-road", or driving use), the user can be fined US$10,000. In the United Kingdom, Belgium and the Netherlands it is known as red diesel (or gas oil), and is also used in agricultural vehicles, home heating tanks, refrigeration units on vans/trucks which contain perishable items (e.g. food, medicine) and for marine craft. Diesel fuel, or Marked Gas Oil is dyed green in the Republic of Ireland. The term DERV ("diesel engined road vehicle") is used in the UK as a synonym for unmarked road diesel fuel. In India, taxes on diesel fuel are lower than on gasoline as the majority of the transportation that transports grains and other essential commodities across the country runs on diesel.
In Germany, diesel fuel is taxed lower than gasoline but the annual vehicle tax is higher for diesel vehicles than for gasoline vehicles. This gives an advantage to vehicles that travel longer distances (which is the case for trucks and utility vehicles) because the annual vehicle tax depends only on engine displacement, not on distance driven. The point at which a diesel vehicle becomes less expensive than a comparable gasoline vehicle is around 20,000 km per year (12,500 miles per year) for an average car.
Taxes on biodiesel in the United States vary from state to state and in some states (Texas, for example) have no tax on biodiesel and a reduced tax on biodiesel blends equivalent to the amount of biodiesel in the blend, so B20 fuel is taxed 20% less than pure petrodiesel. Other states, such as North Carolina, tax biodiesel (in any blended configuration) the same as petrodiesel, although they have introduced new incentives to producers and users of all biofuels.
- macCompanion Magazine
- Table B4, Appendix B, Transportation Energy Data Book from the Center for Transportation Analysis of the Oak Ridge National Laboratory
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- "More Miles To The Gallon". Diesel Technology Forum. Retrieved 2006-11-19.
- "Idle Hour," Feature Article, January 2005
- Agency for Toxic Substances and Disease Registry (ATSDR). 1995. Toxicological profile for fuel oils. Atlanta, GA: U.S. Department of Health and Human Services, Public Health Service
- "http://www.fas.usda.gov/pecad/highlights/2005/01/btl0104/syntheticdiesel.htm". Unknown parameter
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- Is biodiesel cleaner than petrol diesel? at Waste Vegetable Oil Fuels
- Hempcar.org-Pollution: Petrol vs Hemp
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- Torgov, V.G.; Tatarchuk, V.V.; Druzhinina, I.A.; Korda, T.M. et. al, Atomic Energy, 1994, 76(6), 442–448. (Translated from Atomnaya Energiya; 76: No. 6, 478–485 (June 1994))
- http://www.bloomberg.com/apps/news?pid=washingtonstory&sid=aBt.yLf.YfOo Study Pollution Particles Lead to Higher Heart Attack Risk
- United States Government Printing Office (2006-10-25). "Title 26, § 48.4082-1 Diesel fuel and kerosene; exemption for dyed fuel". Electronic Code of Federal Regulations (e-CFR). Retrieved 2006-10-28.
Diesel fuel or kerosene satisfies the dyeing requirement of this paragraph (b) only if the diesel fuel or kerosene contains— (1) The dye Solvent Red 164 (and no other dye) at a concentration spectrally equivalent to at least 3.9 pounds of the solid dye standard Solvent Red 26 per thousand barrels of diesel fuel or kerosene; or (2) Any dye of a type and in a concentration that has been approved by the Commissioner.Check date values in:
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- http://www.eere.energy.gov/afdc/progs/ind_state_laws.php/TX/BIOD Texas Biodiesel Laws and Incentives
- http://www.eere.energy.gov/afdc/progs/ind_state_laws.php/NC/BIOD North Carolina Biodiesel Laws and Incentives
|Wikimedia Commons has media related to Diesel.|
- U.S. Department of Labor Occupational Safety & Health Administration: Safety and Health Topics: Diesel Exhaust
- Diesel Prices in the U.S.
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