Diesel exhaust is the exhaust gas produced by a diesel engine, plus any contained particulates. Its composition may vary with the fuel type, rate of consumption or speed of engine operation (e.g., idling or at speed or under load), and whether the engine is in an on-road vehicle, farm vehicle, locomotive, marine vessel, or stationary generator or other application.[1]

British Rail Class 55 Deltic diesel locomotive with their characteristic dense exhaust when starting a train.

Diesel exhaust causes lung cancer and other diseases such as asthma, and many premature deaths.[2][3][4] Methods exist to reduce nitrogen oxides (NOx) and particulate matter (PM) in the exhaust.

Some countries have set a date to stop selling diesel vehicles, and some city centres will ban diesel cars.[5]

Composition

edit
 
A diesel engine that operates below the smoke limit produces a visible exhaust. In modern motor vehicle diesel engines, this condition is generally avoided by burning the fuel in excess air even at full load.

The primary products of petroleum fuel combustion in air are carbon dioxide, water, and nitrogen. The other components exist primarily from incomplete combustion and pyro synthesis.[1][6] While the distribution of the individual components of raw (untreated) diesel exhaust varies depending on factors like load, engine type, etc., the table below shows a typical composition.

The physical and chemical conditions that exist inside any such diesel engines under any conditions differ considerably from spark-ignition engines, because, by design, diesel engine power is directly controlled by the fuel supply, not by control of the air/fuel mixture, as in conventional gasoline engines.[7] As a result of these differences, diesel engines generally produce a different array of pollutants than spark-driven engines, differences that are sometimes qualitative (what pollutants are there, and what are not), but more often quantitative (how much of particular pollutants or pollutant classes are present in each). For instance, diesel engines produce one-twenty-eighth the carbon monoxide that gasoline engines do, as they burn their fuel in excess air even at full load.[8][9][10]

However, the lean-burning nature of diesel engines and the high temperatures and pressures of the combustion process result in significant production of NOx (gaseous nitrogen oxides), an air pollutant that constitutes a unique challenge with regard to their reduction.[not verified in body] While total nitrogen oxides from petrol cars have decreased by around 96% through the adoption of exhaust catalytic converters as of 2012, diesel cars still produce nitrogen oxides at a similar level to those bought 15 years earlier under real-world tests; hence, diesel cars emit around 20 times more nitrogen oxides than petrol cars.[11][12][13] Modern on-road diesel engines typically use selective catalytic reduction (SCR) systems to meet emissions laws, as other methods such as exhaust gas recirculation (EGR) cannot adequately reduce NOx to meet the newer standards applicable in many jurisdictions.

Moreover, the fine particles (fine particulate matter) in diesel exhaust (e.g., soot, sometimes visible as opaque dark-colored smoke) has traditionally been of greater concern, as it presents different health concerns and is rarely produced in significant quantities by spark-ignition engines. These especially harmful particulate contaminants are at their peak when such engines are run without sufficient oxygen to fully combust the fuel; when a diesel engine runs at idle, enough oxygen is usually present to burn the fuel completely.[14] From the particle emission standpoint, exhaust from diesel vehicles has been reported to be significantly more harmful than those from petrol vehicles.

Diesel exhausts, long known for their characteristic smells, changed significantly with the reduction of the sulfur content of diesel fuel, and again when catalytic converters were introduced in exhaust systems.[not verified in body] Even so, diesel exhausts continue to contain an array of inorganic and organic pollutants, in various classes, and in varying concentrations (see below), depending on fuel composition and engine running conditions.

Diesel engine exhaust compositions[cleanup needed]
Species Average
(Reif 2014)[15]
Average
(Merker,
Teichmann, 2014)[16]
Diesel's first engine
(Hartenstein, 1895)[17]
(Khair, Majewski, 2006)[18] (various sources)
Volume percentage (Volume?)
percentage
Nitrogen (N2) 75.2% 72.1% - ~67 % -
Oxygen (O2) 15% 0.7% 0.5% ~9 % -
Carbon dioxide (CO2) 7.1% 12.3% 12.5% ~12 % -
Water (H2O) 2.6% 13.8% - ~11 % -
Carbon monoxide (CO) 0.043% 0.09% 0.1% - 100–500 ppm[19]
Nitrogen oxides (NOx) 0.034% 0.13% - - 50–1000 ppm[20]
Hydrocarbons (HC) 0.005% 0.09% - - -
Aldehyde 0.001% n/a - - -
Particulate matter
(sulfate + solid substances)
0.008% 0.0008% - - 1–30 mg·m−3[21]

Chemical classes

edit

The following are classes of chemical compounds that have been found in diesel exhaust.[22]

Class of chemical contaminant Note
Antimony compounds[citation needed] Toxicity similar to arsenic poisoning[23]
Beryllium compounds IARC Group 1 carcinogens
Chromium compounds[24] IARC Group 3 possible carcinogens
Cobalt compounds
Cyanide compounds[24]
Dioxins[24] and dibenzofurans
Manganese compounds[24]
Mercury compounds[24] IARC Group 3 possible carcinogens
Nitrogen oxides[24] 5.6 ppm or 6500 μg/m³[1]
Polycyclic organic matter, including
polycyclic aromatic hydrocarbons (PAHs)[1][24]
Selenium compounds
Sulfur compounds[24]

Specific chemicals

edit

The following are classes of specific chemicals that have been found in diesel exhaust.[24][verification needed][needs update][1][page needed]

Chemical contaminant Note Concentration, ppm
Acetaldehyde IARC Group 2B (possible) carcinogens
Acrolein IARC Group 3 possible carcinogens
Aniline IARC Group 3 possible carcinogens
Arsenic IARC Group 1 carcinogens, endocrine disruptor[citation needed]
Benzene[1] IARC Group 1 carcinogens
Biphenyl Mild toxicity[citation needed]
Bis(2-ethylhexyl) phthalate Endocrine disruptor[25][26][27][28]
1,3-Butadiene IARC Group 2A carcinogens
Cadmium IARC Group 1 carcinogens, endocrine disruptor[citation needed]
Chlorine Byproduct of urea injection[citation needed]
Chlorobenzene "[L]ow to moderate" toxicity[29]
Cresol§
Dibutyl phthalate Endocrine disruptor[citation needed]
1,8-Dinitropyrene Strongly carcinogenic[30][31]
Ethylbenzene
Formaldehyde IARC Group 1 carcinogens
Inorganic lead Endocrine disruptor[citation needed]
methanol
Methyl ethyl ketone
Naphthalene IARC Group 2B carcinogens
Nickel IARC Group 2B carcinogens
3-Nitrobenzanthrone (3-NBA) Strongly carcinogenic[30][32] 0.6-6.6[33]
4-Nitrobiphenyl Irritant, damages nerves/liver/kidneys[34] 2.2[35][36]
Phenol
Phosphorus
Pyrene[1] 3532–8002[35][37]
Benzo(e)pyrene 487–946[35][37]
Benzo(a)pyrene IARC Group 1 carcinogen 208–558[35][37]
Fluoranthene[1] IARC Group 3 possible carcinogens 3399–7321[35][37]
Propionaldehyde
Styrene IARC Group 2B carcinogens
Toluene IARC Group 3 possible carcinogens
Xylene§ IARC Group 3 possible carcinogens

§ Includes all regioisomers of this aromatic compound. See ortho-, meta-, and para-isomer descriptions at each compound's article.

Regulation

edit

United States

edit

To rapidly reduce particulate matter from heavy-duty diesel engines in California, the California Air Resources Board created the Carl Moyer Memorial Air Quality Standards Attainment Program to provide funding for upgrading engines ahead of emissions regulations.[38] In 2008, the California Air Resources Board also implemented the 2008 California Statewide Truck and Bus Rule which requires all heavy-duty diesel trucks and buses, with a few exceptions, that operate in California to either retrofit or replace engines in order to reduce diesel particulate matter.[citation needed]

European Union

edit

Unlike international shipping, which had a sulfur limit of 3.5% mass/mass outside ECA until 2020, when it reduced to 0.5% outside ECA, diesel for on road use and off-road (heavy equipment) has been limited throughout the EU since 2009.

Diesel and gasoline have been limited to 10 ppm sulfur since 2009 (for on-road vehicles) and 2011 (non-road vehicles). Mandatory specifications also apply to more than a dozen fuel parameters.[39]

Health damage

edit

Damage to public health

edit

Emissions from diesel vehicles are more harmful than those from petrol vehicles.[40][41][42] Diesel combustion exhaust is a source of atmospheric soot and fine particles, which is a component of the air pollution implicated in human cancer,[43][44] heart and lung damage,[45] and mental functioning.[46] Moreover, diesel exhaust contains contaminants listed as carcinogenic for humans by the IARC (part of the World Health Organization of the United Nations), as present in their List of IARC Group 1 carcinogens.[47] In 2014, diesel exhaust pollution accounted for around one quarter of the pollution in the air and a high share of sickness caused by automotive pollution.[48][better source needed]

Diesel exhaust is a Group 1 carcinogen, which causes lung cancer and has a positive association with bladder cancer.[49][50][51][52][53] It contains several substances that are also listed individually as human carcinogens by the IARC.[47]

Occupational health effects

edit
 
Two diesel particulate matter monitors.

Exposure to diesel exhaust and diesel particulate matter (DPM) is an occupational hazard to truckers, railroad workers, occupants of residential homes in the vicinity of a rail yard, and miners using diesel-powered equipment in underground mines. Adverse health effects have also been observed in the general population at ambient atmospheric particle concentrations well below the concentrations in occupational settings.

In March 2012, U.S. government scientists showed that underground miners exposed to high levels of diesel fumes have a threefold increased risk for contracting lung cancer compared with those exposed to low levels. The $11.5 million Diesel Exhaust in Miners Study (DEMS) followed 12,315 miners, controlling for key carcinogens such as cigarette smoke, radon, and asbestos. This allowed scientists to isolate the effects of diesel fumes.[54][55]

For over 10 years, concerns have been raised in the US regarding children's exposure to DPM as they ride diesel-powered school buses to and from school.[56] In 2013, the Environmental Protection Agency (EPA) established the Clean School Bus USA initiative in an effort to unite private and public organizations in curbing student exposures.[57]

Due to particulates

edit
 
Heavy truck, with visible particulate soot.

Diesel particulate matter (DPM), sometimes also called diesel exhaust particles (DEP), is the particulate component of diesel exhaust, which includes diesel soot and aerosols such as ash particulates, metallic abrasion particles, sulfates, and silicates. When released into the atmosphere, DPM can take the form of individual particles or chain aggregates, with most in the invisible sub-micrometer range of 100 nanometers, also known as ultrafine particles (UFP) or PM0.1.

The main particulate fraction of diesel exhaust consists of fine particles. Because of their small size, inhaled particles may easily penetrate deep into the lungs.[1] The polycyclic aromatic hydrocarbons (PAHs) in the exhaust stimulate nerves in the lungs, causing reflex coughing, wheezing and shortness of breath.[58] The rough surfaces of these particles makes it easy for them to bind with other toxins in the environment, thus increasing the hazards of particle inhalation.[14][verification needed][1]

A study of particulate matter (PM) emissions from transit buses running on ULSD and a mixture of biodiesel and conventional diesel (B20) was reported by Omidvarborna and coworkers, where they concluded that PM emissions appeared lower in cases of mixed diesel/biodiesel use, where they were dependent on the engine model, cold and hot idle modes, and fuel type, and that heavy metals in PM emitted during hot idling were greater than those from cold idling; reasons for PM reduction in biodiesel emissions were suggested to result from the oxygenated structure of biodiesel fuel, as well as arising from changes in technology (including the use of a catalytic converter in this test system).[59] Other studies concluded that while in certain specific cases (i.e. low loads, more saturated feedstocks, ...), NOx emissions can be lower than with diesel fuel, in most cases NOx emissions are higher, and the NOx emissions even go up as more biofuel is mixed in. Pure biodiesel (B100) even ends up having 10-30% more NOx emissions compared to regular diesel fuel.[60]

Specific effects

edit

Exposures have been linked with acute short-term symptoms such as headache, dizziness, light-headedness, nausea, coughing, difficult or labored breathing, tightness of chest, and irritation of the eyes, nose, and throat.[61] Long-term exposures can lead to chronic, more serious health problems such as cardiovascular disease, cardiopulmonary disease, and lung cancer.[43][44][62] Elemental carbon attributable to traffic was significantly associated with wheezing at age 1 and persistent wheezing at age 3 in the Cincinnati Childhood Allergy and Air Pollution Study birth cohort study.[63] Ambient traffic-related air pollution is associated with decreased cognitive function in older men.[46]

The study of nanoparticles and nanotoxicology is in its infancy, and health effects from nanoparticles produced by all types of diesel engines are still being uncovered. It is clear, that diesel health detriments of fine particle emissions are severe and pervasive. Although one study found no significant evidence that short-term exposure to diesel exhaust results in adverse extrapulmonary effects, effects that are correlated with an increase in cardiovascular disease,[64] a 2011 study in The Lancet concluded that traffic exposure is the single most serious preventable trigger of heart attack in the general public, as the cause of 7.4% of all attacks.[45] It is not possible to tell how much of this effect is due to the stress of being in traffic and how much is due to exposure to exhaust.[citation needed]

Since the study of the detrimental health effects of nanoparticles (nanotoxicology) is still in its infancy, and the nature and extent of negative health impacts from diesel exhaust continues to be discovered, it remains controversial whether the public health impact of diesels is higher than that of petrol-fueled vehicles.[65]

Variation with engine conditions

edit

The types and quantities of nanoparticles can vary according to operating temperatures and pressures, the presence of an open flame, fundamental fuel type and fuel mixture, and even atmospheric mixtures. As such, the resulting types of nanoparticles from different engine technologies and even different fuels are not necessarily comparable. One study has shown that 95% of the volatile component of diesel nanoparticles is unburned lubricating oil.[66] Long-term effects still need to be further clarified, as well as the effects on susceptible groups of people with cardiopulmonary diseases.

Diesel engines can produce black soot (or more specifically diesel particulate matter) from their exhaust. The black smoke consists of carbon compounds that have not burned because of local low temperatures where the fuel is not fully atomized. These local low temperatures occur at the cylinder walls, and at the surface of large droplets of fuel. At these areas where it is relatively cold, the mixture is rich (contrary to the overall mixture which is lean). The rich mixture has less air to burn and some of the fuel turns into a carbon deposit. Modern car engines use a diesel particulate filter (DPF) to capture carbon particles and then intermittently burn them using extra fuel injected directly into the filter. This prevents carbon buildup at the expense of wasting a small quantity of fuel.[citation needed]

When starting from cold, the engine's combustion efficiency is reduced because the cold engine block draws heat out of the cylinder in the compression stroke.[67] The result is that fuel is not burned fully, resulting in blue and white smoke and lower power outputs until the engine has warmed. This is especially the case with indirect injection engines, which are less thermally efficient. With electronic injection, the timing and length of the injection sequence can be altered to compensate for this. Older engines with mechanical injection can have mechanical and hydraulic governor control to alter the timing, and multi-phase electrically controlled glow plugs, that stay on for a period after start-up to ensure clean combustion; the plugs are automatically switched to a lower power to prevent their burning out.[citation needed]

Wärtsilä states that there are two ways of forming smoke, on large diesel engines, one being fuel hitting metal and not having time to burn off. The other being, when too much fuel is in the combustion chamber.

Wärtsilä have tested an engine and compared smoke-output, when using conventional fuel system and common rail fuel system, the result shows improvement on all operation conditions when using the common rail system.[68]

Ecological effects

edit

Experiments in 2013 showed that diesel exhaust impaired bees' ability to detect the scent of oilseed rape flowers.[69]

Emissions from diesel engines contribute to the production of ground-level ozone, which can damage crops, trees, and other vegetation. Diesel exhaust also contributes to the formation of acid rain, which affects soil, lakes, and streams, and can enter the human food chain via water, produce, meat, and fish.[70]

Diesel exhaust plays a role in climate change. Reducing greenhouse gas (GHG) emissions from diesel engines through improved fuel economy or idle reduction strategies can help address climate change, improve energy security, and strengthen the economies of countries.[70] While diesel fuel contains slightly more carbon (2.68 kg CO2/litre) than petrol (2.31 kg CO2/litre), overall, the CO2 emissions of a diesel car tend to be lower due to higher efficiency. In use, on average, this equates to around 200 g CO2/km for petrol and 120 g CO2/km for diesel.

Remedies

edit

General

edit

With emission standards tightening, diesel engines are having to become more efficient and have fewer pollutants in their exhaust.[citation needed] Moreover, in recent years the United States, Europe, and Japan have extended emissions control regulations from covering on-road vehicles to include farm vehicles and locomotives, marine vessels, and stationary generator applications.[71] Changing to a different fuel (i.e. dimethyl ether, and other bioethers as diethyl ether)[72] tends to be a very effective means to reduce pollutants such as NOx and CO. When running on dimethyl ether (DME) for instance, particulate matter emissions are near-nonexistent, and the use of diesel particulate filters could even be omitted.[73] Also, given that DME can be made from animal, food, and agricultural waste, it can even be carbon-neutral (unlike regular diesel). Mixing in bio ether (or other fuels such as hydrogen)[74][75] into conventional diesel also tends to have a beneficial effect on the pollutants that are emitted. In addition to changing the fuel, US engineers have also come up with two other principles and distinct systems to all on-market products that meet the U.S. 2010 emissions criteria,[citation needed][needs update] selective non-catalytic reduction (SNCR), and exhaust gas recirculation (EGR). Both are in the exhaust system of diesel engines, and are further designed to promote efficiency.[citation needed]

Selective catalytic reduction

edit

Selective catalytic reduction (SCR) injects a reductant such as ammonia or urea — the latter aqueous, where it is known as diesel exhaust fluid (DEF) — into the exhaust of a diesel engine to convert nitrogen oxides (NOx) into gaseous nitrogen and water. SNCR systems have been prototyped that reduce 90% of the NOx in the exhaust system, with commercialized systems being somewhat lower.[citation needed] SCR systems do not necessarily need particulate matter (PM) filters; when SNCR and PM filters are combined, some engines have been shown to be 3-5% more fuel efficient.[citation needed] A disadvantage of the SCR system, in addition to added upfront development cost (which can be offset by compliance and improved performance),[citation needed] is the need to refill the reductant, the periodicity of which varies with the miles driven, load factors, and the hours used.[76][full citation needed][better source needed][third-party source needed] The SNCR system is not as efficient at higher revolutions per minute (rpm).[citation needed] SCR is being optimized to have higher efficiency with broader temperatures, to be more durable, and to meet other commercial needs.[71]

Exhaust gas recirculation

edit

Exhaust gas recirculation (EGR), on diesel engines, can be used to achieve a richer fuel to air mixture and a lower peak combustion temperature. Both effects reduce NOx emissions, but can negatively impact efficiency and the production of soot particles. The richer mix is achieved by displacing some of the intake air, but is still lean compared to petrol engines, which approach the stoichiometric ideal. The lower peak temperature is achieved by a heat exchanger that removes heat before re-entering the engine, and works due to the exhaust gases' higher specific heat capacity than air. With the greater soot production, EGR is often combined with a particulate matter (PM) filter in the exhaust.[77][full citation needed] In turbocharged engines, EGR needs a controlled pressure differential across the exhaust manifold and intake manifold, which can be met by such engineering as use of a variable geometry turbocharger,[citation needed] which has inlet guide vanes on the turbine to build exhaust backpressure in the exhaust manifold directing exhaust gas to the intake manifold.[77] It also requires additional external piping and valving, and so requires additional maintenance.[citation needed][78]

Combined systems

edit

John Deere, the farm equipment manufacturer, is implementing a combined SCR-EGR design, in a 9-liter "inline 6" diesel engine that involves both system types, a PM filter and additional oxidation catalyst technologies.[79][better source needed][third-party source needed] The combined system incorporates two turbochargers, the first on the exhaust manifold, with variable geometry and containing the EGR system; and a second a fixed geometry turbocharger. Recirculated exhaust gas and the compressed air from the turbochargers have separate coolers, and air merges before entering the intake manifold, and all subsystems are controlled by a central engine control unit that optimizes minimization of pollutants released in the exhaust gas.[79]

Other remedies

edit

A new technology being tested in 2016 has been created by Air Ink which collects carbon particles using a "Kaalink" cylindrical device that is retrofitted into a vehicle's exhaust system, after processing to remove heavy metals and carcinogens, the company plans to use the carbon to make ink.[80]

In India, the Chakr Dual Fuel Kit retrofits a diesel generator set to operate on a mixture of both gas and diesel, with 70% natural gas and 30% fossil fuel.[81]

Water recovery

edit

There has been research into ways that troops in deserts can recover drinkable water from their vehicles' exhaust gases.[82][83][84][85][86]

See also

edit

References and notes

edit
  1. ^ a b c d e f g h i j Lippmann, Morton, ed. (2009). Environmental Toxicants (PDF). pp. 553, 555, 556, 562. doi:10.1002/9780470442890. ISBN 9780470442890. composition can vary markedly with fuel composition, engine type, operating conditions ... combustion of petroleum fuel produces primarily carbon dioxide, water, and nitrogen ... The health risks lie in the small, invisible or poorly visible particles ... carbon (EC) core of diesel soot ... serves as a nucleus for condensation of organic compounds from unburned or incompletely burned fuel ... it still appears that nitrated PAHs are the most predominant bacterial mutagens
  2. ^ "2,700 premature deaths attributed to excess emissions of Diesel cars – MIT LAE". lae.mit.edu. Retrieved 2024-11-19.
  3. ^ "Occupational exposure to diesel exhausts and liver and pancreatic cancers: a systematic review and meta-analysis".
  4. ^ "Vehicular Pollution: New Roadmap To Avoid Millions Of Early Deaths And Cases Of Childhood Asthma - Health Policy Watch". 2024-04-01. Retrieved 2024-11-19.
  5. ^ "Two more cities target diesels". Transport & Environment. 2024-11-05. Retrieved 2024-11-19.
  6. ^ Scheepers, P. T.; Bos, R. P. (1992-01-01). "Combustion of diesel fuel from a toxicological perspective. I. Origin of incomplete combustion products". International Archives of Occupational and Environmental Health. 64 (3): 149–161. Bibcode:1992IAOEH..64..149S. doi:10.1007/bf00380904. ISSN 0340-0131. PMID 1383162. S2CID 4721619.
  7. ^ Song, Chunsham (2000). Chemistry of Diesel Fuels. Boca Raton, FL, US: CRC Press. p. 4. Retrieved 24 October 2015.
  8. ^ Krivoshto, Irina N.; Richards, John R.; Albertson, Timothy E. & Derlet, Robert W. (January 2008). "The Toxicity of Diesel Exhaust: Implications for Primary Care". The Journal of the American Board of Family Medicine. 21 (1): 55–62. doi:10.3122/jabfm.2008.01.070139. PMID 18178703.
  9. ^ Gajendra Babu, M.K.; Subramanian, K.A. (18 June 2013). Alternative Transportation Fuels: Utilisation in Combustion Engines. CRC Press. p. 230. ISBN 9781439872819. Retrieved 24 October 2015. {{cite book}}: |work= ignored (help)
  10. ^ Majewski, W. Addy (2012). "What Are Diesel Emissions". Ecopoint Inc. Retrieved 5 June 2015.[third-party source needed]
  11. ^ Fuller, Gary (Jul 8, 2012). "Diesel cars emit more nitrogen oxides than petrol cars". The Guardian. Retrieved 5 June 2015. New diesels produce similar nitrogen oxides to those bought 15 years ago. Typical modern diesel cars emit around 20 times more nitrogen oxides than petrol cars.
  12. ^ Lean, Geoffrey (Jul 19, 2013). "Why is killer diesel still poisoning our air?". The Telegraph. Retrieved 5 June 2015. Much of the problem is down to EU emission standards, which have long allowed diesel engines to emit much more nitrogen dioxide than petrol ones.
  13. ^ Carslaw D., Beevers; S., Westmoreland E.; Williams, M.; Tate, J.; Murrells, T.; Stedman, J.; Li, Y.; Grice, S.; Kent A & Tsagatakis, I. (2011). Trends in NOX and NO2 emissions and ambient measurements in the UK. London: Department for Environment, Food and Rural Affairs. However, vehicles registered from 2005–2010 emit similar or higher levels of NOx compared with vehicles before 1995. In this respect, NOx emissions from diesel cars have changed little over a period of about 20 years.
  14. ^ a b Omidvarbornaa, Hamid; Kumara, Ashok; Kim, Dong-Shik (2015). "Recent Studies on Soot Modeling for Diesel Combustion". Renewable and Sustainable Energy Reviews. 48: 635–647. Bibcode:2015RSERv..48..635O. doi:10.1016/j.rser.2015.04.019.
  15. ^ Konrad Reif (ed): Dieselmotor-Management im Überblick. 2nd edition. Springer Fachmedien, Wiesbaden 2014, ISBN 978-3-658-06554-6. p. 171
  16. ^ Günter P. Merker, Rüdiger Teichmann (ed.): Grundlagen Verbrennungsmotoren. 7th edition. Springer Fachmedien, Wiesbaden 2014, ISBN 978-3-658-03194-7., Chapter 7.1, Fig. 7.1
  17. ^ Sass, Friedrich (1962), Geschichte des deutschen Verbrennungsmotorenbaus von 1860 bis 1918 (in German), Berlin/Heidelberg: Springer, ISBN 978-3-662-11843-6. p. 466
  18. ^ Resitoglu, Ibrahim Aslan; Altinisik, Kemal; Keskin, Ali (2015). "The pollutant emissions from diesel-engine vehicles and exhaust aftertreatment systems" (PDF). Clean Techn Environ Policy. 17 (1): 17. Bibcode:2015CTEP...17...15R. doi:10.1007/s10098-014-0793-9. S2CID 109912053. Retrieved 20 July 2017.
  19. ^ Grenier, Michael (2005). "Measurement of Carbon Monoxide in Diesel Engine Exhaust" (PDF). IRSST Report (R-436): 11. Retrieved 20 July 2017.
  20. ^ "Gaseous Emissions". DieselNet. Retrieved 21 November 2018.
  21. ^ Tschanz, Frédéric; Amstutz, Alois; Onder, Christopher H.; Guzzella, Lino (2010). "A Real-Time Soot Model for Emission Control of a Diesel Engine". IFAC Proceedings Volumes. 43 (7): 226. doi:10.3182/20100712-3-DE-2013.00107.
  22. ^ Board, California Air Resources. "The Report on Diesel Exhaust". www.arb.ca.gov. Retrieved 2016-10-11. Diesel exhaust includes ... acetaldehyde; antimony compounds; arsenic; benzene; beryllium compounds; bis(2-ethylhexyl)phthalate; dioxins and dibenzofurans; formaldehyde; inorganic lead; mercury compounds; nickel; POM (including PAHs); and styrene.
  23. ^ Gebel, T. (1997-11-28). "Arsenic and antimony: comparative approach on mechanistic toxicology". Chemico-Biological Interactions. 107 (3): 131–144. Bibcode:1997CBI...107..131G. doi:10.1016/s0009-2797(97)00087-2. ISSN 0009-2797. PMID 9448748.
  24. ^ a b c d e f g h i "EPA Report on diesel emissions" (PDF). EPA. 2002. p. 113. Archived from the original (PDF) on 2014-09-10. Retrieved 19 August 2013.
  25. ^ Huang, Li-Ping; Lee, Ching-Chang; Hsu, Ping-Chi; Shih, Tung-Sheng (Jul 2011). "The association between semen quality in workers and the concentration of di(2-ethylhexyl) phthalate in polyvinyl chloride pellet plant air". Fertility and Sterility. 96 (1): 90–94. doi:10.1016/j.fertnstert.2011.04.093. PMID 21621774.
  26. ^ "CDC: Phthalates Overview". 7 September 2021. High doses of di-2-ethylhexyl phthalate (DEHP), dibutyl phthalate (DBP), and benzylbutyl phthalate (BzBP) during the fetal period produced lowered testosterone levels, testicular atrophy, and Sertoli cell abnormalities in the male animals and, at higher doses, ovarian abnormalities in the female animals (Jarfelt et al., 2005; Lovekamp-Swan and Davis, 2003; McKee et al., 2004; NTP-CERHR, 2003a, 2003b, 2006).
  27. ^ Jarfelt, Kirsten; Dalgaard, Majken; Hass, Ulla; Borch, Julie; Jacobsen, Helene; Ladefoged, Ole (2016-10-11). "Antiandrogenic effects in male rats perinatally exposed to a mixture of di(2-ethylhexyl) phthalate and di(2-ethylhexyl) adipate". Reproductive Toxicology (Elmsford, N.Y.). 19 (4): 505–515. doi:10.1016/j.reprotox.2004.11.005. ISSN 0890-6238. PMID 15749265.
  28. ^ Lovekamp-Swan, Tara; Davis, Barbara J. (2003-02-01). "Mechanisms of phthalate ester toxicity in the female reproductive system". Environmental Health Perspectives. 111 (2): 139–145. Bibcode:2003EnvHP.111..139L. doi:10.1289/ehp.5658. ISSN 0091-6765. PMC 1241340. PMID 12573895.
  29. ^ Rossberg, Manfred; Lendle, Wilhelm; Pfleiderer, Gerhard; Tögel, Adolf; Dreher, Eberhard-Ludwig; Langer, Ernst; Rassaerts, Heinz; Kleinschmidt, Peter; Strack, Heinz (2000-01-01). Ullmann's Encyclopedia of Industrial Chemistry. Wiley-VCH Verlag GmbH & Co. KGaA. doi:10.1002/14356007.a06_233.pub2. ISBN 9783527306732.
  30. ^ a b Pearce, Fred. "Devil in the diesel – Lorries belch out what may be the most". New Scientist. Retrieved 2016-10-11.
  31. ^ Enya, Takeji; Suzuki, Hitomi; Watanabe, Tetsushi; Hirayama, Teruhisa; Hisamatsu, Yoshiharu (1997-10-01). "3-Nitrobenzanthrone, a Powerful Bacterial Mutagen and Suspected Human Carcinogen Found in Diesel Exhaust and Airborne Particulates". Environmental Science & Technology. 31 (10): 2772–2776. Bibcode:1997EnST...31.2772E. doi:10.1021/es961067i. ISSN 0013-936X.
  32. ^ Volker M. Arlt (2005). "3-Nitrobenzanthrone, a potential human cancer hazard in diesel exhaust and urban air pollution: a review of the evidence". Mutagenesis. 20 (6): 399–410. doi:10.1093/mutage/gei057. PMID 16199526.
  33. ^ Arlt, Volker M.; Glatt, Hansruedi; Muckel, Eva; Pabel, Ulrike; Sorg, Bernd L.; Seidel, Albrecht; Frank, Heinz; Schmeiser, Heinz H.; Phillips, David H. (2003-07-10). "Activation of 3-nitrobenzanthrone and its metabolites by human acetyltransferases, sulfotransferases and cytochrome P450 expressed in Chinese hamster V79 cells". International Journal of Cancer. 105 (5): 583–592. doi:10.1002/ijc.11143. ISSN 1097-0215. PMID 12740904. S2CID 45714816.
  34. ^ Pubchem. "4-Nitrobiphenyl | C6H5C6H4NO2 - PubChem". pubchem.ncbi.nlm.nih.gov. Retrieved 2016-10-11. Acute (short-term) exposure ... results in irritation of the eyes, mucous membranes, ... Chronic (long-term) exposure ... has resulted in effects on the peripheral and central nervous systems and the liver and kidney.
  35. ^ a b c d e Report on Carcinogens Background Document for Diesel Exhaust Particulates (PDF). National Toxicology Program. December 3, 1998. Concentration (ng/mg extract) ... Concentration (μg/g of particles)
  36. ^ Campbell, Robert M.; Lee, Milton L. (1984-05-01). "Capillary column gas chromatographic determination of nitro polycyclic aromatic compounds in particulate extracts". Analytical Chemistry. 56 (6): 1026–1030. doi:10.1021/ac00270a035. ISSN 0003-2700.
  37. ^ a b c d Tong, H. Y.; Karasek, F. W. (1984-10-01). "Quantitation of polycyclic aromatic hydrocarbons in diesel exhaust particulate matter by high-performance liquid chromatography fractionation and high-resolution gas chromatography". Analytical Chemistry. 56 (12): 2129–2134. doi:10.1021/ac00276a034. ISSN 0003-2700. PMID 6209996.
  38. ^ "Strategic Incentives Division". Bay Area Air Quality Management District.
  39. ^ "EU: Fuels: Diesel and Gasoline | Transport Policy". Retrieved 2019-12-24.
  40. ^ Vidal, John (Jan 27, 2013). "Diesel fumes more damaging to health than petrol engines". The Guardian. Retrieved 5 June 2015.
  41. ^ Dewan, Pandora (2024-02-23). "Breathing in diesel fumes is crippling our immune systems". Newsweek. Retrieved 2024-09-29.
  42. ^ "The health costs of air pollution from cars and vans". Global Action Plan. Retrieved 2024-09-29. the health damage associated with diesel vehicle emissions are …… at least 5 times greater than those associated with petrol vehicles.
  43. ^ a b "Diesel exhausts do cause cancer, says WHO - BBC News". Bbc.co.uk. 2012-06-12. Retrieved 2015-10-22.
  44. ^ a b "WHO: Diesel Exhaust Causes Lung Cancer". Medpage Today. 2012-06-12. Retrieved 2015-10-22.
  45. ^ a b Nawrot, TS; Perez, L; Künzli, N; Munters, E; Nemery, B (2011). "Public health importance of triggers of myocardial infarction: comparative risk assessment". The Lancet. 377 (9767): 732–740. doi:10.1016/S0140-6736(10)62296-9. PMID 21353301. S2CID 20168936.: "Taking into account the OR and the prevalences of exposure, the highest PAF was estimated for traffic exposure (7.4%)... "
    "... [O]dds ratios and frequencies of each trigger were used to compute population-attributable fractions (PAFs), which estimate the proportion of cases that could be avoided if a risk factor were removed. PAFs depend not only on the risk factor strength at the individual level but also on its frequency in the community. ... [T]he exposure prevalence for triggers in the relevant control time window ranged from 0.04% for cocaine use to 100% for air pollution. ... Taking into account the OR and the prevalences of exposure, the highest PAF was estimated for traffic exposure (7.4%) ...
  46. ^ a b Power; Weisskopf; Alexeeff; Coull; Spiro; Schwartz (May 2011). "Traffic-related air pollution and cognitive function in a cohort of older men". Environmental Health Perspectives. 119 (5): 682–7. Bibcode:2011EnvHP.119..682P. doi:10.1289/ehp.1002767. PMC 3094421. PMID 21172758. Archived from the original on 2014-11-21.
  47. ^ a b IARC. "Diesel Engine Exhaust Carcinogenic" (Press release). International Agency for Research on Cancer (IARC). Retrieved June 12, 2012. After a week-long meeting of international experts, the International Agency for Research on Cancer (IARC), which is part of the World Health Organization (WHO), today classified diesel exhaust as probably carcinogenic to humans (Group 1), based on enough evidence that exposure is associated with an increased risk of lung cancer.
  48. ^ Health Concerns Associated with Excessive Idling Archived 2014-01-16 at the Wayback Machine North Central Texas Council of Governments, 2008.[better source needed]
  49. ^ "IARC: DIESEL ENGINE EXHAUST CARCINOGENIC" (Press release). International Agency for Research on Cancer (IARC). June 12, 2012. Retrieved August 14, 2016. The scientific evidence was reviewed thoroughly by the Working Group and overall it was concluded that there was sufficient evidence in humans for the carcinogenicity of diesel exhaust. The Working Group found that diesel exhaust is a cause of lung cancer (sufficient evidence) and also noted a positive association (limited evidence) with an increased risk of bladder cancer
  50. ^ "Report on Carcinogens: Diesel Exhaust Particulates" (PDF). National Toxicology Program, Department of Health and Human Services. October 2, 2014. Exposure to diesel exhaust particulates is reasonably anticipated to be a human carcinogen, based on limited evidence of carcinogenicity from studies in humans and supporting evidence from studies in experimental animals and mechanistic studies.
  51. ^ "Diesel engine exhaust; CASRN N.A." (PDF). U.S. Environmental Protection Agency. 2003-02-28. Using U.S. EPA's revised draft 1999 Guidelines for Carcinogen Risk Assessment (U.S. EPA, 1999), diesel exhaust (DE) is likely to be carcinogenic to humans by inhalation from environmental exposures.
  52. ^ Silverman, Debra T.; Samanic, Claudine M.; Lubin, Jay H.; Blair, Aaron E.; Stewart, Patricia A.; Vermeulen, Roel; Coble, Joseph B.; Rothman, Nathaniel; Schleiff, Patricia L. (2012-06-06). "The Diesel Exhaust in Miners study: a nested case-control study of lung cancer and diesel exhaust". Journal of the National Cancer Institute. 104 (11): 855–868. doi:10.1093/jnci/djs034. ISSN 1460-2105. PMC 3369553. PMID 22393209.
  53. ^ Attfield, Michael D.; Schleiff, Patricia L.; Lubin, Jay H.; Blair, Aaron; Stewart, Patricia A.; Vermeulen, Roel; Coble, Joseph B.; Silverman, Debra T. (2012-06-06). "The Diesel Exhaust in Miners study: a cohort mortality study with emphasis on lung cancer". Journal of the National Cancer Institute. 104 (11): 869–883. doi:10.1093/jnci/djs035. ISSN 1460-2105. PMC 3373218. PMID 22393207.
  54. ^ Attfield, M. D.; Schleiff, P. L.; Lubin, J. H.; Blair, A.; Stewart, P. A.; Vermeulen, R.; Coble, J. B.; Silverman, D. T. (5 March 2012). "The Diesel Exhaust in Miners Study: A Cohort Mortality Study With Emphasis on Lung Cancer". JNCI Journal of the National Cancer Institute. 104 (11): 869–883. doi:10.1093/jnci/djs035. PMC 3373218. PMID 22393207.
  55. ^ Silverman, D. T.; Samanic, C. M.; Lubin, J. H.; Blair, A. E.; Stewart, P. A.; Vermeulen, R.; Coble, J. B.; Rothman, N.; Schleiff, P. L.; Travis, W. D.; Ziegler, R. G.; Wacholder, S.; Attfield, M. D. (5 March 2012). "The Diesel Exhaust in Miners Study: A Nested Case-Control Study of Lung Cancer and Diesel Exhaust". JNCI Journal of the National Cancer Institute. 104 (11): 855–868. doi:10.1093/jnci/djs034. PMC 3369553. PMID 22393209.
  56. ^ Solomon, Gina; Campbell, Todd (January 2001). "No Breathing in the Aisles. Diesel Exhaust Inside School Buses". NRDC.org. Natural Resources Defense Council. Retrieved 19 October 2013.
  57. ^ "Clean School Bus". EPA.gov. United States Government. Retrieved 19 October 2013.
  58. ^ "How diesel fumes could cause 'flare up' of respiratory symptoms". ScienceDaily. Retrieved 25 July 2023.
  59. ^ Omidvarbornaa, Hamid; Kumara, Ashok; Kim, Dong-Shik (2014). "Characterization of Particulate Matter Emitted from Transit Buses Fueled with B20 in Idle Modes". Journal of Environmental Chemical Engineering. 2 (4, December): 2335–2342. doi:10.1016/j.jece.2014.09.020.
  60. ^ "Effects of Biodiesel on Emissions". dieselnet.com. Retrieved 25 July 2023.
  61. ^ "Tox Town - Diesel - Toxic chemicals and environmental health risks where you live and work - Text Version". toxtown.nlm.nih.gov. Archived from the original on 2017-02-04. Retrieved 2017-02-04.
  62. ^ Ole Raaschou-Nielsen; et al. (July 10, 2013). "Air pollution and lung cancer incidence in 17 European cohorts: prospective analyses from the European Study of Cohorts for Air Pollution Effects (ESCAPE)". The Lancet Oncology. 14 (9): 813–22. doi:10.1016/S1470-2045(13)70279-1. PMID 23849838. Archived from the original on July 15, 2013. Retrieved July 10, 2013. Particulate matter air pollution contributes to lung cancer incidence in Europe.
  63. ^ Bernstein, David I. (Jul 2012). "Diesel Exhaust Exposure, Wheezing and Sneezing". Allergy Asthma Immunol Res. 4 (4): 178–183. doi:10.4168/aair.2012.4.4.178. PMC 3378923. PMID 22754710.
  64. ^ "Congress of the International Society on Thrombosis and Haemostasis". www.blackwellpublishing.com. Archived from the original on January 30, 2009.
  65. ^ Int Panis, L; Rabl; De Nocker, L; Torfs, R (2002). "Diesel or Petrol ? An environmental comparison hampered by uncertainty". Mitteilungen Institut für Verbrennungskraftmaschinen und Thermodynamik, Publisher: Institut für Verbrennungskraftmaschinen und Thermodynamik. 81 (1): 48–54.
  66. ^ Sakurai, Hiromu; Tobias, Herbert J.; Park, Kihong; Zarling, Darrick; Docherty, Kenneth S.; Kittelson, David B.; McMurry, Peter H.; Ziemann, Paul J. (2003). "On-line measurements of diesel nanoparticle composition and volatility". Atmospheric Environment. 37 (9–10): 1199–1210. Bibcode:2003AtmEn..37.1199S. doi:10.1016/S1352-2310(02)01017-8.
  67. ^ "Understanding Diesel Engine Cold Start: Causes, Effects, And Solutions | FuelFlowPro". fuelflowpro.com. 2023-04-12. Retrieved 2024-04-12.
  68. ^ Pounder's marine diesel engines and gas turbines. Woodyard, D. F. (Douglas F.) (9th ed.). Amsterdam: Elsevier/Butterworth-Heinemann. 2009. pp. 84, 85. ISBN 978-0-08-094361-9. OCLC 500844605.{{cite book}}: CS1 maint: others (link)
  69. ^ Poppy, Guy M.; Newman, Tracey A.; Farthing, Emily; Lusebrink, Inka; Girling, Robbie D. (2013-10-03). "Diesel exhaust rapidly degrades floral odours used by honeybees : Scientific Reports". Scientific Reports. 3: 2779. doi:10.1038/srep02779. PMC 3789406. PMID 24091789.
  70. ^ a b Reşitoğlu, İbrahim Aslan; Altinişik, Kemal; Keskin, Ali (2015-01-01). "The pollutant emissions from diesel-engine vehicles and exhaust aftertreatment systems". Clean Technologies and Environmental Policy. 17 (1): 15–27. Bibcode:2015CTEP...17...15R. doi:10.1007/s10098-014-0793-9. ISSN 1618-9558.  This article incorporates text from this source, which is available under the CC BY 4.0 license.
  71. ^ a b Guan, B; Zhan, R; Lin, H; Huang, Z. (2014). "Review of state of the art technologies of selective catalytic reduction of NOx from diesel engine exhaust". Applied Thermal Engineering. 66 (1–2): 395–414. doi:10.1016/j.applthermaleng.2014.02.021. (subscription required)
  72. ^ "Simultaneous reduction of NOx and smoke from a direct-injection diesel engine with exhaust gas recirculation and diethyl ether | Request PDF". Retrieved 25 July 2023.
  73. ^ "Alternative Fuels Data Center: Dimethyl Ether". afdc.energy.gov. Retrieved 25 July 2023.
  74. ^ Talibi, Midhat; Hellier, Paul; Balachandran, Ramanarayanan; Ladommatos, Nicos (12 September 2014). "Effect of hydrogen-diesel fuel co-combustion on exhaust emissions with verification using an in–cylinder gas sampling technique". International Journal of Hydrogen Energy. 39 (27): 15088–15102. Bibcode:2014IJHE...3915088T. doi:10.1016/j.ijhydene.2014.07.039.
  75. ^ "Innovations | Eden Innovations". 28 June 2016. Retrieved 25 July 2023.
  76. ^ "What is SCR? | Diesel Technology Forum". Dieselforum.org. 2010-01-01. Archived from the original on 2015-10-08. Retrieved 2015-10-22.
  77. ^ a b Bennett, Sean (2004). Medium/Heavy Duty Truck Engines, Fuel & Computerized Management Systems 2nd Edition, ISBN 1401814999.[full citation needed][page needed]
  78. ^ Goswami, Angshuman; Barman, Jyotirmoy; Rajput, Karan; Lakhlani, Hardik N. (2013). "Behaviour Study of Particulate Matter and Chemical Composition with Different Combustion Strategies". SAE Technical Paper Series. Vol. 1. doi:10.4271/2013-01-2741. Retrieved 2016-06-17.
  79. ^ a b "Technology to Reduce Emissions in Large Engines" (PDF). Deere.com. Retrieved 2015-10-22.
  80. ^ "These Pens Use Ink Made Out Of Recycled Air Pollution". IFL Science. 17 August 2016.
  81. ^ "Chakr Innovation launches Dual Fuel Kit to provide first Turnkey Solution to DG set ban in Delhi-NCR". news.webindia123.com. Retrieved 2023-05-30.
  82. ^ "Article title" (PDF). Retrieved 25 July 2023.
  83. ^ "Recovery and purification of water from the exhaust gases of int ernal combustion engines". Retrieved 25 July 2023.
  84. ^ Barros, Sam; Atkinson, William; Piduru, Naag (2015). "Extraction of Liquid Water from the Exhaust of a Diesel Engine". SAE Technical Paper Series. Vol. 1. doi:10.4271/2015-01-2806.
  85. ^ "Apparatus and method of recovering water from engine exhaust gases".
  86. ^ "Newsroom | Department of Energy".

Further reading

edit
edit