Earth:Air pollution

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Short description: Presence of dangerous substances in the atmosphere


Air pollution from a coking oven
2016 Environmental Performance Index – darker colors indicate lower concentrations of fine particulate matter and nitrogen dioxide, as well as better indoor air quality.
Deaths from air pollution per 100,000 inhabitants (IHME, 2019)

Air pollution is the contamination of air due to the presence of substances called pollutants in the atmosphere that are harmful to the health of humans and other living beings, or cause damage to the climate or to materials.[1] It is also the contamination of the indoor or outdoor environment either by chemical, physical, or biological agents that alters the natural features of the atmosphere.[1] There are many different types of air pollutants, such as gases (including ammonia, carbon monoxide, sulfur dioxide, nitrous oxides, methane and chlorofluorocarbons), particulates (both organic and inorganic), and biological molecules. Air pollution can cause diseases, allergies, and even death to humans; it can also cause harm to other living organisms such as animals and crops, and may damage the natural environment (for example, climate change, ozone depletion or habitat degradation) or built environment (for example, acid rain).[2] Air pollution can be caused by both human activities[3] and natural phenomena.[4]

Air quality is closely related to the earth's climate and ecosystems globally. Many of the contributors of air pollution are also sources of greenhouse emission i.e., burning of fossil fuel.[1]

Air pollution is a significant risk factor for a number of pollution-related diseases, including respiratory infections, heart disease, chronic obstructive pulmonary disease (COPD), stroke, and lung cancer.[5] Growing evidence suggests that air pollution exposure may be associated with reduced IQ scores, impaired cognition,[6] increased risk for psychiatric disorders such as depression[7] and detrimental perinatal health.[8] The human health effects of poor air quality are far reaching, but principally affect the body's respiratory system and the cardiovascular system. Individual reactions to air pollutants depend on the type of pollutant a person is exposed to,[9][10] the degree of exposure, and the individual's health status and genetics.[11]

Outdoor air pollution attributable to fossil fuel use alone causes ~3.61 million deaths annually, making it one of the top contributors to human death,[5][12] with anthropogenic ozone and PM2.5 causing ~2.1 million.[13][14] Overall, air pollution causes the deaths of around 7 million people worldwide each year, or a global mean loss of life expectancy (LLE) of 2.9 years,[15] and is the world's largest single environmental health risk, which has not shown significant progress since at least 2015.[5][16][17][18] Indoor air pollution and poor urban air quality are listed as two of the world's worst toxic pollution problems in the 2008 Blacksmith Institute World's Worst Polluted Places report.[19] The scope of the air pollution crisis is large: In 2018, WHO estimated that "9 out of 10 people breathe air containing high levels of pollutants."[20] Although the health consequences are extensive, the way the problem is handled is considered largely haphazard[21][20][22] or neglected.[18]

Productivity losses and degraded quality of life caused by air pollution are estimated to cost the world economy $5 trillion per year[23][24][25] but, along with health and mortality impacts, are an externality to the contemporary economic system and most human activity, albeit sometimes being moderately regulated and monitored.[26][27] Various pollution control technologies and strategies are available to reduce air pollution.[28][29] Several international and national legislation and regulation have been developed to limit the negative effects of air pollution.[30] Local rules, when properly executed, have resulted in significant advances in public health.[31] Some of these efforts have been successful at the international level, such as the Montreal Protocol,[32] which reduced the release of harmful ozone depleting chemicals, and the 1985 Helsinki Protocol,[33] which reduced sulfur emissions,[34] while others, such as international action on climate change,[35][36][37] have been less successful.

Sources of air pollution

Anthropogenic (human-made) sources

Demolition of the cooling towers of a power station, Athlone, Cape Town, South Africa, 2010
Controlled burning of a field outside of Statesboro, Georgia, US, in preparation for spring planting
Smoking of fish over an open fire in Ghana, 2018
  • Stationary sources include:
    • fossil-fuel power plants and biomass power plants both have smoke stacks (see for example environmental impact of the coal industry)[38]
    • burning of traditional biomass such as wood, crop waste and dung. (In developing and poor countries,[43] traditional biomass burning is the major source of air pollutants.[44][45] It is also the main source of particulate pollution in many developed areas including the UK & New South Wales.[46][47] Its pollutants include PAHs.[48])
    • manufacturing facilities (factories)[49]
      • a 2014 study found that in China equipment-, machinery-, and devices-manufacturing and construction sectors contributed more than 50% of air pollutant emissions.[50][better source needed] This high emission is due to high emission intensity and high emission factors in its industrial structure.[51]
    • construction[52][53]
    • waste incineration (incinerators as well as open and uncontrolled fires of mismanaged waste, making up about a fourth of municipal solid terrestrial waste)[54][55]
    • furnaces and other types of fuel-burning heating devices[56]
  • Mobile sources include motor vehicles, Trains (particularly diesel locomotives and DMUs), marine vessels and aircraft[57] as well as rockets and re-entry of components and debris.[58] The air pollution externality of cars enters the air from the exhaust gas and car tires (including microplastics[59]). Vehicles were reported to be "producing about one-third of all U.S. air pollution"[60][better source needed] and are a major driver of climate change.[61][62]
  • Agriculture and forest management strategies using controlled burns. Practices like slash-and-burn in forests like the Amazon cause large air pollution with the deforestation.[63] Controlled or prescribed burning is a practice used in forest management, agriculture, prairie restoration, and greenhouse gas reduction.[64] Foresters can use controlled fire as a tool because fire is a natural feature of both forest and grassland ecology.[65][66] Controlled burning encourages the sprouting of some desirable forest trees, resulting in a forest renewal.[67]

There are also sources from processes other than combustion:

  • Fumes from paint, hair spray, varnish, aerosol sprays and other solvents. These can be substantial; emissions from these sources was estimated to account for almost half of pollution from volatile organic compounds in the Los Angeles basin in the 2010s.[68]
  • Waste deposition in landfills produces methane[69] and open burning of waste releases harmful substances.[70]
  • Nuclear weapons, toxic gases, germ warfare, and rocketry are examples of military resources.[71]
  • Agricultural emissions and emissions from meat production or livestock contribute substantially to air pollution[72][73]
Mean acidifying emissions (air pollution) of different foods per 100g of protein[75]
Food Types Acidifying Emissions (g SO2eq per 100g protein)
Beef
343.6
Cheese
165.5
Pork
142.7
Lamb and mutton
139.0
Farmed crustaceans
133.1
Poultry
102.4
Farmed fish
65.9
Eggs
53.7
Groundnuts
22.6
Peas
8.5
Tofu
6.7

Natural sources

Dust storm approaching Stratford, Texas, in 1935
  • Dust from natural sources, usually large areas of land with little vegetation or no vegetation
  • Methane, emitted by the digestion of food by animals, for example cattle
  • Radon gas from radioactive decay within the Earth's crust. Radon is a colorless, odorless, naturally occurring, radioactive noble gas that is formed from the decay of radium. It is considered to be a health hazard. Radon gas from natural sources can accumulate in buildings, especially in confined areas such as the basement and it is the second most frequent cause of lung cancer, after cigarette smoking.
  • Smoke and carbon monoxide from wildfires. During periods of active wildfires, smoke from uncontrolled biomass combustion can make up almost 75% of all air pollution by concentration.[76]
  • Vegetation, in some regions, emits environmentally significant amounts of volatile organic compounds (VOCs) on warmer days. These VOCs react with primary anthropogenic pollutants – specifically, NOx, SO2, and anthropogenic organic carbon compounds – to produce a seasonal haze of secondary pollutants.[77] Black gum, poplar, oak and willow are some examples of vegetation that can produce abundant VOCs. The VOC production from these species result in ozone levels up to eight times higher than the low-impact tree species.[78]
  • Volcanic activity, which produces sulfur, chlorine, and ash particulates[79]

Emission factors

Beijing air in 2005 after rain (left) and a smoggy day (right)

Air pollutant emission factors are reported representative values that aim to link the quantity of a pollutant released into the ambient air to an activity connected with that pollutant's release.[2][80][81][82] The weight of the pollutant divided by a unit weight, volume, distance, or time of the activity generating the pollutant is how these factors are commonly stated (e.g., kilograms of particulate emitted per tonne of coal burned). These criteria make estimating emissions from diverse sources of pollution easier. Most of the time, these components are just averages of all available data of acceptable quality, and they are thought to be typical of long-term averages.

There are 12 compounds in the list of persistent organic pollutants. Dioxins and furans are two of them and intentionally created by combustion of organics, like open burning of plastics. These compounds are also endocrine disruptors and can mutate the human genes.

E-waste processing in Agbogbloshie, Ghana, using open-burning of electronics to access valuable metals like copper. Open burning of plastics is common in many parts of the world without the capacity for processing. Especially without proper protections, heavy metals and other contaminates can seep into the soil, and create water pollution and air pollution.

The United States Environmental Protection Agency has published a compilation of air pollutant emission factors for a wide range of industrial sources.[83] The United Kingdom, Australia, Canada, and many other countries have published similar compilations, as well as the European Environment Agency.[84][85][86][87]

Pollutants

Main pages: Chemistry:Pollutant and Earth:Greenhouse gas emissions
Schematic drawing, causes and effects of air pollution: (1) greenhouse effect, (2) particulate contamination, (3) increased UV radiation, (4) acid rain, (5) increased ground-level ozone concentration, (6) increased levels of nitrogen oxides

An air pollutant is a material in the air that can have many effects on humans and the ecosystem.[88] The substance can be solid particles, liquid droplets, or gases, and often takes the form of an aerosol (solid particles or liquid droplets dispersed and carried by a gas).[89] A pollutant can be of natural origin or man-made. Pollutants are classified as primary or secondary. Primary pollutants are usually produced by processes such as ash from a volcanic eruption.

Other examples include carbon monoxide gas from motor vehicle exhausts or sulfur dioxide released from factories. Secondary pollutants are not emitted directly. Rather, they form in the air when primary pollutants react or interact. Ground level ozone is a prominent example of a secondary pollutant. Some pollutants may be both primary and secondary: they are both emitted directly and formed from other primary pollutants.

Primary pollutants

Pollutants emitted into the atmosphere by human activity include:

  • Ammonia: Emitted mainly by agricultural waste. Ammonia is a compound with the formula NH3. It is normally encountered as a gas with a characteristic pungent odor. Ammonia contributes significantly to the nutritional needs of terrestrial organisms by serving as a precursor to foodstuffs and fertilizers. Ammonia, either directly or indirectly, is also a building block for the synthesis of many pharmaceuticals. Although in wide use, ammonia is both caustic and hazardous.[90] In the atmosphere, ammonia reacts with oxides of nitrogen and sulfur to form secondary particles.[91]
  • Carbon dioxide (CO
    2
    ): Carbon dioxide is a natural component of the atmosphere, essential for plant life and given off by the human respiratory system.[92] It is potentially lethal at very high concentrations (typically 100 times "normal" atmospheric levels).[93][94] Although the World Health Organization recognizes CO
    2
    as a climate pollutant, it does not include the gas in its Air Quality Guidelines or set recommended targets for it.[95] Because of its role as a greenhouse gas, CO
    2
    has been described as "the worst climate pollutant".[96] Statements such as this refer to its long-term atmospheric effects rather than shorter-term effects on such things as human health, food crops, and buildings. This question of terminology has practical consequences, for example, in determining whether the U.S. Clean Air Act (which is designed to improve air quality) is deemed to regulate CO
    2
    emissions.[97] That issue was resolved in the United States by the Inflation Reduction Act of 2022, which specifically amended the Clean Air Act "to define the carbon dioxide produced by the burning of fossil fuels as an 'air pollutant.'"[98] CO
    2
    currently forms about 410 parts per million (ppm) of Earth's atmosphere, compared to about 280 ppm in pre-industrial times,[99] and billions of metric tons of CO
    2
    are emitted annually by burning of fossil fuels.[100] CO
    2
    increase in Earth's atmosphere has been accelerating.[101] CO
    2
    is an asphyxiant gas and not classified as toxic or harmful in general.[102] Workplace exposure limits exist in places like UK (5,000 ppm for long-term exposure and 15,000 ppm for short-term exposure).[94] Natural disasters like the limnic eruption at Lake Nyos can result in a sudden release of huge amount of CO
    2
    as well.[103]
  • Carbon monoxide (CO): CO is a colorless, odorless, toxic gas.[104] It is a product of combustion of fuel such as natural gas, coal or wood. Vehicular exhaust contributes to the majority of carbon monoxide let into the atmosphere. It creates a smog type formation in the air that has been linked to many lung diseases and disruptions to the natural environment and animals.
  • Chlorofluorocarbons (CFCs): Emitted from goods that are now prohibited from use; harmful to the ozone layer. These are gases emitted by air conditioners, freezers, aerosol sprays, and other similar devices. CFCs reach the stratosphere after being released into the atmosphere.[105] They interact with other gases here, causing harm to the ozone layer. UV rays are able to reach the Earth's surface as a result of this. This can result in skin cancer, eye problems, and even plant damage.[106]
  • Nitrogen oxides (NOx): Nitrogen oxides, particularly nitrogen dioxide, are expelled from high temperature combustion, and are also produced during thunderstorms by electric discharge. They can be seen as a brown haze dome above or a plume downwind of cities. Nitrogen dioxide is a chemical compound with the formula NO2. It is one of several nitrogen oxides. One of the most prominent air pollutants, this reddish-brown toxic gas has a characteristic sharp, biting odor.
  • Odors: Such as from garbage, sewage, and industrial processes.
  • Particulate matter/particles (PM), also known as particulates, atmospheric particulate matter (APM), or fine particles, are microscopic solid or liquid particles suspended in a gas.[107] Aerosol is a mixture of particles and gas. Volcanoes, dust storms, forest and grassland fires, living plants, and sea spray are all sources of particles. Aerosols are produced by human activities such as the combustion of fossil fuels in automobiles, power plants, and numerous industrial processes.[108] Averaged worldwide, anthropogenic aerosols – those made by human activities – currently account for approximately 10% of the atmosphere. Increased levels of fine particles in the air are linked to health hazards such as heart disease,[109] altered lung function and lung cancer. Particulates are related to respiratory infections and can be particularly harmful to those with conditions like asthma.[110]
  • Persistent organic pollutants, which can attach to particulates. Persistent organic pollutants are organic compounds that are resistant to environmental degradation due to chemical, biological, or photolytic processes (POPs). As a result, they've been discovered to survive in the environment, be capable of long-range transmission, bioaccumulate in human and animal tissue, biomagnify in food chains, and pose a major threat to human health and the ecosystem.[111]
  • Persistent free radicals connected to airborne fine particles are linked to cardiopulmonary disease.[112][113]
  • Polycyclic Aromatic Hydrocarbons (PAHs): a group of aromatic compounds formed from the incomplete combustion of organic compounds including coal and oil and tobacco.[114]
  • Radioactive pollutants: Produced by nuclear explosions, nuclear events, war explosives, and natural processes such as the radioactive decay of radon.
  • Sulfur oxides (SOx): particularly sulfur dioxide, a chemical compound with the formula SO2. SO2 is produced by volcanoes and in various industrial processes. Coal and petroleum often contain sulfur compounds, and their combustion generates sulfur dioxide. Further oxidation of SO2, usually in the presence of a catalyst such as NO2, forms H2SO4, and thus acid rain is formed. This is one of the causes for concern over the environmental impact of the use of these fuels as power sources.
  • Toxic metals, such as lead and mercury, especially their compounds.
  • Volatile organic compounds (VOC): VOCs are both indoor and outdoor air pollutants.[115] They are categorized as either methane (CH4) or non-methane (NMVOCs). Methane is an extremely efficient greenhouse gas which contributes to enhanced global warming. Other hydrocarbon VOCs are also significant greenhouse gases because of their role in creating ozone and prolonging the life of methane in the atmosphere. This effect varies depending on local air quality. The aromatic NMVOCs benzene, toluene and xylene are suspected carcinogens and may lead to leukemia with prolonged exposure. 1,3-butadiene is another dangerous compound often associated with industrial use.

Secondary pollutants

Secondary pollutants include:

  • Ground level ozone (O3): Ozone is created when NOx and VOCs mix. It is a significant part of the troposphere.[116] It's also an important part of the ozone layer, which can be found in different sections of the stratosphere. Photochemical and chemical reactions involving it fuel many of the chemical activities that occur in the atmosphere during the day and night. It is a pollutant and a component of smog that is produced in large quantities as a result of human activities (mostly the combustion of fossil fuels).[117]
  • Peroxyacetyl nitrate (C2H3NO5): similarly formed from NOx and VOCs.
  • Photochemical smog: particles are formed from gaseous primary contaminants and chemicals.[118] Smog is a type of pollution that occurs in the atmosphere. Smog is caused by a huge volume of coal being burned in a certain region, resulting in a mixture of smoke and sulfur dioxide.[119] Modern smog is usually caused by automotive and industrial emissions, which are acted on in the atmosphere by UV light from the sun to produce secondary pollutants, which then combine with the primary emissions to generate photochemical smog.

Other pollutants

There are many other chemicals classed as hazardous air pollutants. Some of these are regulated in the USA under the Clean Air Act and in Europe under numerous directives (including the Air "Framework" Directive, 96/62/EC, on ambient air quality assessment and management, Directive 98/24/EC, on risks related to chemical agents at work, and Directive 2004/107/EC covering heavy metals and polycyclic aromatic hydrocarbons in ambient air).[120][121]

To display all pages, subcategories and images click on the "►":
Hazardous air pollutants(4 C, 69 P)

Exposure

In 2012, up to 30% of Europeans living in cities are exposed to air pollutant levels exceeding EU air quality standards. Around 98% of Europeans living in cities are exposed to levels of air pollutants deemed damaging to health by the World Health Organization's more stringent guidelines.[122]

The risk of air pollution is determined by the pollutant's hazard and the amount of exposure to that pollutant. Air pollution exposure can be measured for a person, a group, such as a neighborhood or a country's children, or an entire population. For example, one would want to determine a geographic area's exposure to a dangerous air pollution, taking into account the various microenvironments and age groups. This can be calculated[11] as an inhalation exposure. This would account for daily exposure in various settings, e.g. different indoor micro-environments and outdoor locations. The exposure needs to include different ages and other demographic groups, especially infants, children, pregnant women, and other sensitive subpopulations.[11]

For each specific time that the subgroup is in the setting and engaged in particular activities, the exposure to an air pollutant must integrate the concentrations of the air pollutant with regard to the time spent in each setting and the respective inhalation rates for each subgroup, playing, cooking, reading, working, spending time in traffic, etc. A little child's inhaling rate, for example, will be lower than that of an adult. A young person engaging in strenuous exercise will have a faster rate of breathing than a child engaged in sedentary activity. The daily exposure must therefore include the amount of time spent in each micro-environmental setting as well as the kind of activities performed there. The air pollutant concentration in each microactivity/microenvironmental setting is summed to indicate the exposure.[11]

For some pollutants such as black carbon, traffic related exposures may dominate total exposure despite short exposure times since high concentrations coincide with proximity to major roads or participation in (motorized) traffic.[123] A large portion of total daily exposure occurs as short peaks of high concentrations, but it remains unclear how to define peaks and determine their frequency and health impact.[124]

In 2021, the WHO halved its recommended guideline limit for tiny particles from burning fossil fuels. The new limit for nitrogen dioxide (NO2) is 75% lower.[125] Growing evidence that air pollution—even when experienced at very low levels—hurts human health, led the WHO to revise its guideline (from 10 µg/m³ to 5 µg/m³) for what it considers a safe level of exposure of particulate pollution, bringing most of the world—97.3 percent of the global population—into the unsafe zone.[126]

Indoor air quality

The share of total deaths from indoor air pollution, 2017
Air quality monitoring, New Delhi, India

A lack of ventilation indoors concentrates air pollution where people often spend the majority of their time. Radon (Rn) gas, a carcinogen, is exuded from the Earth in certain locations and trapped inside houses. Building materials including carpeting and plywood emit formaldehyde (H-CHO) gas. Paint and solvents give off volatile organic compounds (VOCs) as they dry. Lead paint can degenerate into dust and be inhaled.[127][128]

Intentional air pollution is introduced with the use of air fresheners, incense, and other scented items. Controlled wood fires in cook stoves and fireplaces can add significant amounts of harmful smoke particulates into the air, inside and out.[127][128] Indoor pollution fatalities may be caused by using pesticides and other chemical sprays indoors without proper ventilation. Also the kitchen in a modern produce harmful particles and gases, with equipment like toasters being one of the worst sources.[129]

Carbon monoxide poisoning and fatalities are often caused by faulty vents and chimneys, or by the burning of charcoal indoors or in a confined space, such as a tent.[130] Chronic carbon monoxide poisoning can result even from poorly-adjusted pilot lights. Traps are built into all domestic plumbing to keep sewer gas and hydrogen sulfide, out of interiors. Clothing emits tetrachloroethylene, or other dry cleaning fluids, for days after dry cleaning.

Though its use has now been banned in many countries, the extensive use of asbestos in industrial and domestic environments in the past has left a potentially very dangerous material in many localities. Asbestosis is a chronic inflammatory medical condition affecting the tissue of the lungs. It occurs after long-term, heavy exposure to asbestos from asbestos-containing materials in structures. Those with asbestosis have severe dyspnea (shortness of breath) and are at an increased risk regarding several different types of lung cancer. As clear explanations are not always stressed in non-technical literature, care should be taken to distinguish between several forms of relevant diseases. According to the World Health Organization,[131] these may be defined as asbestosis, lung cancer, and peritoneal mesothelioma (generally a very rare form of cancer, when more widespread it is almost always associated with prolonged exposure to asbestos).

Biological sources of air pollution are also found indoors, as gases and airborne particulates. Pets produce dander, people produce dust from minute skin flakes and decomposed hair, dust mites in bedding, carpeting and furniture produce enzymes and micrometre-sized fecal droppings, inhabitants emit methane, mold forms on walls and generates mycotoxins and spores, air conditioning systems can incubate Legionnaires' disease and mold, and houseplants, soil and surrounding gardens can produce pollen, dust, and mold. Indoors, the lack of air circulation allows these airborne pollutants to accumulate more than they would otherwise occur in nature.

Health effects

Even at levels lower than those considered safe by United States regulators, exposure to three components of air pollution, fine particulate matter, nitrogen dioxide and ozone, correlates with cardiac and respiratory illness.[132] In 2020, pollution (including air pollution) was a contributing factor to one in eight deaths in Europe, and was a significant risk factor for pollution-related diseases including heart disease, stroke and lung cancer.[133] The health effects caused by air pollution may include difficulty in breathing, wheezing, coughing, asthma[134] and worsening of existing respiratory and cardiac conditions. These effects can result in increased medication use, increased doctor or emergency department visits, more hospital admissions and premature death.[11]

The human health effects of poor air quality are far reaching, but principally affect the body's respiratory system and the cardiovascular system. Individual reactions to air pollutants depend on the type of pollutant a person is exposed to, the degree of exposure, and the individual's health status and genetics.[11] The most common sources of air pollution include particulates, ozone, nitrogen dioxide, and sulfur dioxide. Children aged less than five years who live in developing countries are the most vulnerable population in terms of total deaths attributable to indoor and outdoor air pollution.[135] Under the Clean Air Act, U.S. EPA sets limits on certain air pollutants, including setting limits on how much can be in the air anywhere in the United States.[136] New research demonstrates that the biological and health outcomes of mixed exposures (Example PM + Ozone) could be significantly greater than individual exposures.[137]

Air pollution has both acute and chronic effects on human health, affecting a number of different systems and organs. It ranges from minor upper respiratory irritation to chronic respiratory and heart disease, lung cancer, acute respiratory infections in children and chronic bronchitis in adults, aggravating pre-existing heart and lung disease, or asthmatic attacks. Short and long term exposures have been linked with premature mortality and reduced life expectancy.[138] Diseases that develop from persistent exposure to air pollution are environmental health diseases, which develop when a health environment is not maintained.[139]

Mortality

How-many-people-die-from-air-pollution-1-1.png
Deaths caused by accidents and air pollution from fossil fuel use in power plants exceed those caused by production of renewable energy.[140]
The share of total deaths from outdoor air pollution, by nation

The World Health Organization estimated in 2014 that every year air pollution causes the premature death of some 7 million people worldwide.[5] Studies published in March 2019 indicated that the number may be around 8.8 million.[141] A 2022 review concluded that air pollution was responsible for 6.67 (5.90–7.49) million premature deaths in 2019. It concluded that since 2015 little real progress against (superordinate) pollution, which remained at ~9 million earlier deaths, can be identified.[142][18] Causes of deaths include strokes, heart disease, COPD, lung cancer, and lung infections.[5]

Urban outdoor air pollution is estimated to cause 1.3 million deaths worldwide per year.[143] Children are particularly at risk due to the immaturity of their respiratory organ systems.[144] In 2015, outdoor air pollution, mostly by PM2.5, was estimated to lead to 3.3 (95% CI 1.61–4.81) million premature deaths per year worldwide, predominantly in Asia.[73] In 2021, the WHO reported that outdoor air pollution was estimated to cause 4.2 million premature deaths worldwide in 2016.[145]

A 2020 study indicates that the global mean loss of life expectancy (LLE; similar to YPLL) from air pollution in 2015 was 2.9 years, substantially more than, for example, 0.3 years from all forms of direct violence, albeit a significant fraction of the LLE is unavoidable.[15] Communities with the most exceptional aging have low ambient air pollution, suggesting a link between air pollution levels and longevity.[146]

A study published in 2022 in GeoHealth concluded that eliminating energy-related fossil fuel emissions in the United States would prevent 46,900–59,400 premature deaths each year and provide $537–$678 billion in benefits from avoided PM2.5-related illness and death.[147]

By region

India and China have the highest death rate due to air pollution.[148][149] India also has more deaths from asthma than any other nation according to the World Health Organization. In 2019, 1.6 million deaths in India were caused by air pollution.[150] In December 2013, air pollution was estimated to kill 500,000 people in China each year.[151] There is a positive correlation between pneumonia-related deaths and air pollution from motor vehicle emissions.[152]

Annual premature European deaths caused by air pollution are estimated at 430,000[153] to 800,000.[141] An important cause of these deaths is nitrogen dioxide and other nitrogen oxides (NOx) emitted by road vehicles.[153] In a 2015 consultation document the UK government disclosed that nitrogen dioxide is responsible for 23,500 premature UK deaths per annum.[154] Across the European Union, air pollution is estimated to reduce life expectancy by almost nine months.[155]

Guidelines

Main page: Earth:Air quality guideline

The US EPA has estimated that limiting ground-level ozone concentration to 65 parts per billion (ppb), would avert 1,700 to 5,100 premature deaths nationwide in 2020 compared with the 75 ppb standard. The agency projected the more protective standard would also prevent an additional 26,000 cases of aggravated asthma, and more than a million cases of missed work or school.[156][157] Following this assessment, the EPA acted to protect public health by lowering the National Ambient Air Quality Standards (NAAQS) for ground-level ozone to 70 ppb.[158]

A 2008 economic study of the health impacts and associated costs of air pollution in the Los Angeles Basin and San Joaquin Valley of Southern California shows that more than 3,800 people die prematurely (approximately 14 years earlier than normal) each year because air pollution levels violate federal standards. The number of annual premature deaths is considerably higher than the fatalities related to auto collisions in the same area, which average fewer than 2,000 per year.[159][160][161] A 2021 study found that outdoor air pollution is associated with substantially increased mortality "even at low pollution levels below the current European and North American standards and WHO guideline values" shortly before the WHO adjusted its guidelines.[162][163]

Major causes

A comparison of footprint-based and transboundary pollution-based relationships among G20 nations for the number of PM2.5-related premature deaths[164]

The largest cause is air pollution generated by fossil fuel combustion[165] – mostly the production and use of cars, electricity production, and heating.[166] A study by Greenpeace estimates there are 4.5 million annual premature deaths worldwide because of pollutants released by high-emission power stations and vehicle exhausts.[167]

Diesel exhaust (DE) is a major contributor to combustion-derived particulate matter air pollution. In several human experimental studies, using a well-validated exposure chamber setup, DE has been linked to acute vascular dysfunction and increased thrombus formation.[168][169]

A study concluded that PM2.5 air pollution induced by the contemporary free trade and consumption by the 19 G20 nations causes two million premature deaths annually, suggesting that the average lifetime consumption of about ~28 people in these countries causes at least one premature death (average age ~67) while developing countries "cannot be expected" to implement or be able to implement countermeasures without external support or internationally coordinated efforts.[170][164]

Primary mechanisms

The WHO estimates that in 2016, ~58% of outdoor air pollution-related premature deaths were due to ischaemic heart disease and stroke.[145] The mechanisms linking air pollution to increased cardiovascular mortality are uncertain, but probably include pulmonary and systemic inflammation.[171]

Contemporary annual deaths

A 2021 study by scientists of U.K. and U.S. universities that uses a high spatial resolution model and an updated concentration-response function concluded that 10.4 million global excess deaths in 2012 and 8.7 million in 2018 – or a fifth[dubious ] – were due to air pollution generated by fossil fuel combustion, significantly higher than earlier estimates and with spatially subdivided mortality impacts.[172][165]

According to the WHO, air pollution accounts for 1 in 8 deaths worldwide.[173]

Cardiovascular disease

A 2007 review of evidence found that for the general population, ambient air pollution exposure is a risk factor correlating with increased total mortality from cardiovascular events (range: 12% to 14% per 10 µg/m3 increase).[174][clarification needed]

Air pollution is emerging as a risk factor for stroke, particularly in developing countries where pollutant levels are highest.[175] A 2007 study found that in women, air pollution is not associated with hemorrhagic but with ischemic stroke.[176] Air pollution was found to be associated with increased incidence and mortality from coronary stroke in a cohort study in 2011.[177] Associations are believed to be causal and effects may be mediated by vasoconstriction, low-grade inflammation and atherosclerosis.[178] Other mechanisms such as autonomic nervous system imbalance have also been suggested.[179][180]

Lung disease

Research has demonstrated increased risk of developing asthma[181] and chronic obstructive pulmonary disease (COPD)[182] from increased exposure to traffic-related air pollution. Air pollution has been associated with increased hospitalization and mortality from asthma and COPD.[183][184] COPD includes diseases such as chronic bronchitis and emphysema.[185] The risk of lung disease from air pollution is greatest for the following groups of people: infants and young children, whose normal breathing is faster than that of older children and adults; the elderly; those who work outside or spend a lot of time outside; and those who have heart or lung disease.[186]

A study conducted in 1960–1961 in the wake of the Great Smog of 1952 compared 293 London residents with 477 residents of Gloucester, Peterborough, and Norwich, three towns with low reported death rates from chronic bronchitis. All subjects were male postal truck drivers aged 40 to 59. Compared to the subjects from the outlying towns, the London subjects exhibited more severe respiratory symptoms (including cough, phlegm, and dyspnea), reduced lung function (FEV1 and peak flow rate), and increased sputum production and purulence. The differences were more pronounced for subjects aged 50 to 59. The study controlled for age and smoking habits, so concluded that air pollution was the most likely cause of the observed differences.[187] More studies have shown that air pollution exposure from traffic reduces lung function development in children[188] and lung function may be compromised by air pollution even at low concentrations.[189]

It is believed that much like cystic fibrosis, by living in a more urban environment serious health hazards become more apparent. Studies have shown that in urban areas people experience mucus hypersecretion, lower levels of lung function, and more self-diagnosis of chronic bronchitis and emphysema.[190]

COPD comprises a spectrum of clinical disorders that include emphysema, bronchiectasis, and chronic bronchitis. COPD risk factors are both genetic and environmental. Elevated particle pollution contributes to the exacerbation of this disease and likely its pathogenesis.[191]

Cancer (lung cancer)

Unprotected exposure to PM2.5 air pollution can be equivalent to smoking multiple cigarettes per day,[192] potentially increasing the risk of cancer, which is mainly the result of environmental factors.[193]

Around 300,000 lung cancer deaths were attributed globally in 2019 to exposure to fine particulate matter, PM2.5, contained in air pollution.[194]

A review of evidence regarding whether ambient air pollution exposure is a risk factor for cancer in 2007 found solid data to conclude that long-term exposure to PM2.5 (fine particulates) increases the overall risk of non-accidental mortality by 6% per a 10 μg/m3 increase. Exposure to PM2.5 was also associated with an increased risk of mortality from lung cancer (range: 15–21% per 10 μg/m3 increase) and total cardiovascular mortality (range: 12–14% per a 10 μg/m3 increase).[174]

The review further noted that living close to busy traffic appears to be associated with elevated risks of these three outcomes – increase in lung cancer deaths, cardiovascular deaths, and overall non-accidental deaths. The reviewers also found suggestive evidence that exposure to PM2.5 is positively associated with mortality from coronary heart diseases and exposure to SO2 increases mortality from lung cancer, but the data was insufficient to provide solid conclusions.[174] Another investigation showed that higher activity level increases deposition fraction of aerosol particles in human lung and recommended avoiding heavy activities like running in outdoor space at polluted areas.[195]

In 2011, a large Danish epidemiological study found an increased risk of lung cancer for people who lived in areas with high nitrogen oxide concentrations. In this study, the association was higher for non-smokers than smokers.[196] An additional Danish study, also in 2011, likewise noted evidence of possible associations between air pollution and other forms of cancer, including cervical cancer and brain cancer.[197]

A study presented in 2022 outlined the biological basis for how air pollution causes cancer.[194]

Kidney disease

In 2021, a study of 163,197 Taiwanese residents over the period of 2001–2016 estimated that every 5 μg/m3 decrease in the ambient concentration of PM2.5 was associated with a 25% reduced risk of chronic kidney disease development.[198] According to a chord study involving 10,997 atherosclerosis patients, higher PM 2.5 exposure is associate with increased albuminuria.[199]

Fertility

NO2

In women undergoing IVF treatment, increases in NO2 both at the patient's address and by the IVF lab were significantly associated with a lower live birth rate.[200]

In the general population, there is a significant increase in miscarriage rate in women exposed to NO2 compared to the non-exposed group.[200]

CO

CO exposure is significantly associated with stillbirth in the second and third trimester.[200]

Standard line-angle structure of benzo-a-pyrene (BaP)

Polycyclic aromatic hydrocarbons

Polycyclic aromatic hydrocarbons (PAHs) have been associated with reduced fertility. Benzo(a)pyrene (BaP) is a well-known PAH and carcinogen which is often found in exhaust fumes and cigarette smoke.[201] PAHs have been reported to administer their toxic effects through oxidative stress by increasing the production of Reactive Oxygen Species (ROS) which can result in inflammation and cell death. More long-term exposure to PAHs can result in DNA damage and reduced repair.[202]

Exposure to BaP has been reported to reduce sperm motility and increasing the exposure worsens this effect. Research has demonstrated that more BaPs were found in men with reported fertility issues compared to men without.[203]

Studies have shown that BaPs can affect folliculogenesis and ovarian development by reducing the number of ovarian germ cells via triggering cell death pathways and inducing inflammation which can lead to ovarian damage.[204]

Particulate matter

Particulate matter (PM) refers to the collection of solids and liquids suspended in the air. These can be harmful to humans when exposed to in day-to-day life, and more research has shown that these effects may be more extensive than first thought; particularly on male fertility. Within the spectrum of PM there are different weights, such as PM2.5 which are tiny particles of 2.5 microns in width or smaller, compared with PM10 which are classified as 10 microns in diameter or less.

In a study based in California it was found that as exposure to PM2.5 increased sperm motility decreased and morphology became more abnormal. Similarly, in Poland exposure to PM2.5 and PM10 lead to an increase in the percentage of cells with immature chromatin (DNA that has not fully developed or has developed abnormally).[205]

In Turkey, a study looked at the fertility of men who work as toll collectors and are therefore exposed to high levels of traffic pollutants daily. Traffic pollution often has high levels of PM10 alongside carbon monoxide and nitrous oxides.[205] In this study group there were significant differences in sperm count and motility when compared to a control group with limited air pollution exposure.

In women, whilst overall effects on fertility did not seem significant there was an association was found between increased exposure to PM10 and early miscarriage. Exposure to smaller particulate matter, PM2.5, was seen to have an effect on conception rates in women undergoing IVF but not with live birth rates.[200]

Ozone structure showing three oxygen atoms

Ground-level ozone pollution

Ground-level ozone (O3), when in high concentrations, is regarded as an air pollutant and is often found in smog in industrial areas. O3 is largely produced by chemical reactions involving NOx gases (nitrous oxides, especially from combustion) and volatile organic compounds in the presence of sunlight.

There is limited research about the effect that ozone pollution has on fertility.[200] At present, there is no evidence to suggest that ozone exposure poses a deleterious effect on spontaneous fertility in either females or males. However, there have been studies which suggest that high levels of ozone pollution, often a problem in the summer months, exert an effect on in vitro fertilisation (IVF) outcomes. Within an IVF population, NOx and ozone pollutants were linked with reduced rates of live birth.[200]

While most research on this topic is focused on the direct human exposure of air pollution, other studies have analysed the impact of air pollution on gametes and embryos within IVF laboratories. Multiple studies have reported a marked improvement in embryo quality, implantation and pregnancy rates after IVF laboratories have implemented air filters in a concerted effort to reduce levels of air pollution.[206] Therefore, ozone pollution is considered to have a negative impact on the success of assisted reproductive technologies (ART) when occurring at high levels.

Ozone is thought to act in a biphasic manner where a positive effect on live birth is observed when ozone exposure is limited to before IVF embryo implantation.[207] Conversely, a negative effect is demonstrated upon exposure to ozone after embryo implantation.[208]

Retrospective and prospective studies evaluating the effect of several traffic pollutants (of which ground-level ozone is one) highlighted a significant decrease in live birth rates and miscarriages.[206]

In terms of male fertility, ozone is reported to cause a significant decrease in sperm concentration measured in semen after exposure.[209] Similarly, sperm vitality, the proportion of alive spermatozoa in a sample, was demonstrated to be diminished in a handful of studies.[208] This demonstrates that ozone air pollution exhibits a significantly negative effect of air pollution on this parameter. However, findings on the effect of ozone exposure on male fertility are somewhat discordant, highlighting the need for further research.[208]

Children

In the United States, despite the passage of the Clean Air Act in 1970, in 2002 at least 146 million Americans were living in non-attainment areas – regions in which the concentration of certain air pollutants exceeded federal standards.[210] These dangerous pollutants are known as the criteria pollutants, and include ozone, particulate matter, sulfur dioxide, nitrogen dioxide, carbon monoxide, and lead. Protective measures to ensure children's health are being taken in cities such as New Delhi, India, where buses now use compressed natural gas to help eliminate the "pea-soup" smog.[211] A 2015 study in Europe has found that exposure to ultrafine particles can increase blood pressure in children.[212] In a 2018 WHO report, polluted air leads to the poisoning of millions of children under the age of 15, resulting in the death of some six hundred thousand children annually.[213]

Prenatal exposure

Prenatal exposure to polluted air has been linked to a variety of neurodevelopmental disorders in children. For example, exposure to polycyclic aromatic hydrocarbons (PAH) was associated with reduced IQ scores and symptoms of anxiety and depression.[214] They can also lead to detrimental perinatal health outcomes that are often fatal in developing countries.[8] A 2014 study found that PAHs might play a role in the development of childhood attention deficit hyperactivity disorder (ADHD).[215]

Researchers have begun to find evidence for air pollution as a risk factor for autism spectrum disorder (ASD). In Los Angeles, children who were living in areas with high levels of traffic-related air pollution were more likely to be diagnosed with autism between three–five years of age.[216] The connection between air pollution and neurodevelopmental disorders in children is thought to be related to epigenetic dysregulation of the primordial germ cells, embryo, and fetus during a critical period. Some PAHs are considered endocrine disruptors and are lipid soluble. When they build up in adipose tissue, they can be transferred across the placenta.[217] Air pollution has been associated with the prevalence of preterm births.[218]

Infants

Ambient levels of air pollution have been associated with preterm birth and low birth weight. A 2014 WHO worldwide survey on maternal and perinatal health found a statistically significant association between low birth weights (LBW) and increased levels of exposure to PM2.5. Women in regions with greater than average PM2.5 levels had statistically significant higher odds of pregnancy resulting in a low-birth weight infant even when adjusted for country-related variables.[219] The effect is thought to be from stimulating inflammation and increasing oxidative stress.

A study by the University of York found that in 2010 exposure to PM2.5 was strongly associated with 18% of preterm births globally, which was approximately 2.7 million premature births. The countries with the highest air pollution associated preterm births were in South and East Asia, the Middle East, North Africa, and West sub-Saharan Africa.[220] In 2019, ambient particulate matter pollution in Africa resulted in at least 383,000 early deaths, according to new estimates of the cost of air pollution in the continent. This increased from 3.6% in 1990 to around 7.4% of all premature deaths in the area.[221][222][223]

The source of PM2.5 differs greatly by region. In South and East Asia, pregnant women are frequently exposed to indoor air pollution because of wood and other biomass fuels being used for cooking, which are responsible for more than 80% of regional pollution. In the Middle East, North Africa and West sub-Saharan Africa, fine PM comes from natural sources, such as dust storms.[220] The United States had an estimated 50,000 preterm births associated with exposure to PM2.5 in 2010.[220]

A study between 1988 and 1991 found a correlation between sulfur dioxide (SO2) and total suspended particulates (TSP) and preterm births and low birth weights in Beijing. A group of 74,671 pregnant women, in four separate regions of Beijing, were monitored from early pregnancy to delivery along with daily air pollution levels of sulfur Dioxide and TSP (along with other particulates). The estimated reduction in birth weight was 7.3 g for every 100 µg/m3 increase in SO
2
and 6.9 g for each 100 µg/m3 increase in TSP. These associations were statistically significant in both summer and winter, although, summer was greater. The proportion of low birth weight attributable to air pollution, was 13%. This is the largest attributable risk ever reported for the known risk factors of low birth weight.[224] Coal stoves, which are in 97% of homes, are a major source of air pollution in this area.

Brauer et al. studied the relationship between air pollution and proximity to a highway with pregnancy outcomes in a Vancouver cohort of pregnant woman using addresses to estimate exposure during pregnancy. Exposure to NO, NO2, CO, PM10 and PM2.5 were associated with infants born small for gestational age (SGA). Women living less than 50 meters away from an expressway or highway were 26% more likely to give birth to a SGA infant.[225]

"Clean" areas

The share of the population exposed to air pollution levels above WHO guidelines, 2016

Even in areas with relatively low levels of air pollution, public health effects can be significant and costly, since a large number of people breathe in such pollutants. A study published in 2017 found that even in areas of the U.S. where ozone and PM2.5 meet federal standards, Medicare recipients who are exposed to more air pollution have higher mortality rates.[226]

A 2005 scientific study for the British Columbia Lung Association showed that a small improvement in air quality (1% reduction of ambient PM2.5 and ozone concentrations) would produce $29 million in annual savings in the Metro Vancouver region in 2010.[227] This finding is based on health valuation of lethal (death) and sub-lethal (illness) affects. A study published in 2022 found that rural population in India, like those in urban areas, are also exposed to high levels of air pollution.[228]

In 2020, scientists found that the boundary layer air over the Southern Ocean around Antarctica is 'unpolluted' by humans.[229]

Central nervous system

Data is accumulating that air pollution exposure also affects the central nervous system.[230]

Air pollution increases the risk of dementia in people over 50 years old.[231] Childhood indoor air pollution may negatively affect cognitive function and neurodevelopment.[232][233] Prenatal exposure may also affect neurodevelopment.[234][235] Studies show that air pollution is associated with a variety of developmental disabilities, oxidative stress, and neuro-inflammation and that it may contribute to Alzheimer's disease and Parkinson's disease.[233]

Researchers at the University of Rochester Medical Center found that early exposure to air pollution causes the same changes in the brain as autism and schizophrenia. This study was published in the journal Environmental Health Perspectives, in June 2014. It also showed that air pollution also affected short-term memory, learning ability, and impulsivity. Lead researcher Deborah Cory-Slechta said that:

When we looked closely at the ventricles, we could see that the white matter that normally surrounds them hadn't fully developed. It appears that inflammation had damaged those brain cells and prevented that region of the brain from developing, and the ventricles simply expanded to fill the space. Our findings add to the growing body of evidence that air pollution may play a role in autism, as well as in other neurodevelopmental disorders.

Exposure to fine particulate matter can increase levels of cytokines - neurotransmitters produced in response to infection and inflammation that are also associated with depression and suicide. Pollution has been associated with inflammation of the brain, which may disrupt mood regulation. According to a study of Washington DC's American University, heightened PM2.5 levels are linked to more self-reported depressive symptoms, and increases in daily suicide rates.[236]

In a study of mice, air pollution also has a larger negative impact on males than on females.[237][238][239]

In 2015, experimental studies reported the detection of significant episodic (situational) cognitive impairment from impurities in indoor air breathed by test subjects who were not informed about changes in the air quality. Researchers at the Harvard University and SUNY Upstate Medical University and Syracuse University measured the cognitive performance of 24 participants in three different controlled laboratory atmospheres that simulated those found in "conventional" and "green" buildings, as well as green buildings with enhanced ventilation. Performance was evaluated objectively using the widely used Strategic Management Simulation software simulation tool, which is a well-validated assessment test for executive decision-making in an unconstrained situation allowing initiative and improvisation. Significant deficits were observed in the performance scores achieved in increasing concentrations of either volatile organic compounds (VOCs) or carbon dioxide, while keeping other factors constant. The highest impurity levels reached are not uncommon in some classroom or office environments.[240][241] Higher PM2.5 and CO
2
concentrations were shown to be associated with slower response times and reduced accuracy in tests.[242]

Agricultural effects

Various studies have estimated the impacts of air pollution on agriculture, especially ozone. A 2020 study showed that ozone pollution in California may reduce yields of certain perennial crops such as table grapes by as much as 22% per year, translating into economic damages of more than $1 billion per year.[243] After air pollutants enter the agricultural environment, they not only directly affect agricultural production and quality, but also enter agricultural waters and soil.[244] The COVID-19 induced lockdown served as a natural experiment to expose the close links between air quality and surface greenness. In India, the lockdown induced improvement in air quality, enhanced surface greenness and photosynthetic activity, with the positive response of vegetation to reduce air pollution was dominant in croplands.[245] On the other hand, agriculture in its traditional form is one of the primary contributors to the emission of trace gases like atmospheric ammonia.[246]

Economic effects

Air pollution costs the world economy $5 trillion per year as a result of productivity losses and degraded quality of life, in a 2016 joint study by the World Bank and the Institute for Health Metrics and Evaluation (IHME) at the University of Washington.[23][24][25] These productivity losses are caused by deaths due to diseases caused by air pollution. One out of ten deaths in 2013 was caused by diseases associated with air pollution and the problem is getting worse. The problem is even more acute in the developing world. "Children under age 5 in lower-income countries are more than 60 times as likely to die from exposure to air pollution as children in high-income countries."[23][24] The report states that additional economic losses caused by air pollution, including health costs[247] and the adverse effect on agricultural and other productivity were not calculated in the report, and thus the actual costs to the world economy are far higher than $5 trillion. A study published in 2022 found "a strong and significant connection between air pollution and construction site accidents" and that "a 10-ppb increase in NO₂ levels increases the likelihood of an accident by as much as 25 percent".[248]

Other effects

Artificial air pollution may be detectable on Earth from distant vantage points such as other planetary systems via atmospheric SETI – including NO2 pollution levels and with telescopic technology close to today. It may also be possible to detect extraterrestrial civilizations this way.[249][250][251]

Historical disasters

The world's worst short-term civilian pollution crisis was the 1984 Bhopal Disaster in India.[252] Leaked industrial vapours from the Union Carbide factory, belonging to Union Carbide, Inc., U.S.A. (later bought by Dow Chemical Company), killed at least 3787 people and injured from 150,000 to 600,000. The United Kingdom suffered its worst air pollution event when the 4 December Great Smog of 1952 formed over London. In six days more than 4,000 died and more recent estimates put the figure at nearer 12,000.[253]

An accidental leak of anthrax spores from a biological warfare laboratory in the former USSR in 1979 near Yekaterinburg (formerly Sverdlovsk) is believed to have caused at least 64 deaths.[254] The worst single incident of air pollution to occur in the US occurred in Donora, Pennsylvania, in late October 1948, when 20 people died and over 7,000 were injured.[255]

Reduction and regulation

Global depletion of the surrounding air pollution will require valiant leadership, a surplus of combined resources from the international community, and extensive societal changes.[256] Pollution prevention seeks to prevent pollution such as air pollution and could include adjustments to industrial and business activities such as designing sustainable manufacturing processes (and the products' designs)[257] and related legal regulations as well as efforts towards renewable energy transitions.[258][259]

Efforts to reduce particulate matter in the air may result in better health.[260]

The 9-Euro-Ticket scheme in Germany which allowed people to buy a monthly pass allowing use on all local and regional transport (trains, trams and busses) for 9 euro (€) for one month of unlimited travel saved 1.8 million tons of CO
2
emissions during its three-month implementation from June to August 2022.[261]

Pollution control

Burning of items polluting Jamestown environment in Accra, Ghana

Various pollution control technologies and strategies are available to reduce air pollution.[28][29] At its most basic level, land-use planning is likely to involve zoning and transport infrastructure planning. In most developed countries, land-use planning is an important part of social policy, ensuring that land is used efficiently for the benefit of the wider economy and population, as well as to protect the environment.[262] Stringent environmental regulations, effective control technologies and shift towards the renewable source of energy also helping countries like China and India to reduce their sulfur dioxide pollution.[263]

Titanium dioxide has been researched for its ability to reduce air pollution. Ultraviolet light will release free electrons from material, thereby creating free radicals, which break up VOCs and NO
x
gases. One form is superhydrophilic.[264]

Pollution-eating nanoparticles placed near a busy road were shown to absorb toxic emission from around 20 cars each day.[265]

Energy transition

Since a large share of air pollution is caused by combustion of fossil fuels such as coal and oil, the reduction of these fuels can reduce air pollution drastically. Most effective is the switch to clean power sources such as wind power, solar power, hydro power which do not cause air pollution.[266] Efforts to reduce pollution from mobile sources includes expanding regulation to new sources (such as cruise and transport ships, farm equipment, and small gas-powered equipment such as string trimmers, chainsaws, and snowmobiles), increased fuel efficiency (such as through the use of hybrid vehicles), conversion to cleaner fuels, and conversion to electric vehicles.

A very effective means to reduce air pollution is the transition to renewable energy. According to a study published in Energy and Environmental Science in 2015 the switch to 100% renewable energy in the United States would eliminate about 62,000 premature mortalities per year and about 42,000 in 2050, if no biomass were used. This would save about $600 billion in health costs a year due to reduced air pollution in 2050, or about 3.6% of the 2014 U.S. gross domestic product.[266] Air quality improvement is a near-term benefit among the many societal benefits from climate change mitigation.

Alternatives to pollution

Support for a ban on high-emission vehicles in city centres in Europe, China and the US from respondents to the European Investment Bank Climate Survey
Support, use and infrastructure-expansion of forms of public transport that do not cause air pollution may be a critical key alternative to pollution.

There are now practical alternatives to the principal causes of air pollution:

  • Strategic substitution of air pollution sources in transport with lower-emission or, during the lifecycle, emission-free forms of public transport[267][268] and bicycle use and infrastructure (as well as with remote work, reductions of work, relocations, and localizations)
    • Phase-out of fossil fuel vehicles is a critical component of a shift to sustainable transport; however, similar infrastructure and design decisions like electric vehicles may be associated with similar pollution for production as well as mining and resource exploitation for large numbers of needed batteries as well as the energy for their recharging[269][270]
  • Areas downwind (over 20 miles) of major airports have more than double total particulate emissions in air than other areas, even when factoring in areas with frequent ship calls, and heavy freeway and city traffic like Los Angeles.[271] Aviation biofuel mixed in with jetfuel at a 50/50 ratio can reduce jet derived cruise altitude particulate emissions by 50–70%, according to a NASA led 2017 study (however, this should imply ground level benefits to urban air pollution as well).[272]
  • Ship propulsion and idling can be switched to much cleaner fuels like natural gas. (Ideally a renewable source but not practical yet)
  • Combustion of fossil fuels for space heating can be replaced by using ground source heat pumps and seasonal thermal energy storage.[273]
  • Electricity generated from the combustion of fossil fuels can be replaced by nuclear and renewable energy. Heating and home stoves, which contribute significantly to regional air pollution, can be replaced with a much cleaner fossil fuel, such as natural gas, or, preferably, renewables, in poor countries.[274][275]
  • Motor vehicles driven by fossil fuels, a key factor in urban air pollution, can be replaced by electric vehicles. Though lithium supply and cost is a limitation, there are alternatives. Herding more people into clean public transit such as electric trains can also help. Nevertheless, even in emission-free electric vehicles, rubber tires produce significant amounts of air pollution themselves, ranking as 13th worst pollutant in Los Angeles.[276]
  • Reducing travel in vehicles can curb pollution. After Stockholm reduced vehicle traffic in the central city with a congestion tax, nitrogen dioxide and PM10 pollution declined, as did acute pediatric asthma attacks.[277]
  • Biodigesters can be utilized in poor nations where slash and burn is prevalent, turning a useless commodity into a source of income. The plants can be gathered and sold to a central authority that will break them down in a large modern biodigester, producing much needed energy to use.[278]
  • Induced humidity and ventilation both can greatly dampen air pollution in enclosed spaces, which was found to be relatively high inside subway lines due to braking and friction and relatively less ironically inside transit buses than lower sitting passenger automobiles or subways.[279]

Control devices

Tarps and netting are often used to reduce the amount of dust released from construction sites.
Air pollution from a car

The following items are commonly used as pollution control devices in industry and transportation. They can either destroy contaminants or remove them from an exhaust stream before it is emitted into the atmosphere.


Monitoring

Air quality modeling

Main page: Earth:Air quality modeling

Numerical models either on a global scale using tools such as GCMs (general circulation models coupled with a pollution module) or CTMs (Chemical transport model) can be used to simulate the levels of different pollutants in the atmosphere. These tools can have several types (Atmospheric model) and different uses. These models can be used in forecast mode which can help policy makers to decide on appropriate actions when an air pollution episode is detected. They can also be used for climate modeling including evolution of air quality in the future, for example the IPCC (Intergovernmental Panel on Climate Change) provides climate simulations including air quality assessments in their reports (latest report accessible through their site).

Regulations

Main page: Earth:Air quality law
Smog in Cairo

In general, there are two types of air quality standards. The first class of standards (such as the U.S. National Ambient Air Quality Standards and E.U. Air Quality Directive[280]) set maximum atmospheric concentrations for specific pollutants. Environmental agencies enact regulations which are intended to result in attainment of these target levels. The second class (such as the North American air quality index) take the form of a scale with various thresholds, which is used to communicate to the public the relative risk of outdoor activity. The scale may or may not distinguish between different pollutants.

Canada

In Canada, air pollution and associated health risks are measured with the Air Quality Health Index (AQHI).[281] It is a health protection tool used to make decisions to reduce short-term exposure to air pollution by adjusting activity levels during increased levels of air pollution.

The AQHI is a federal program jointly coordinated by Health Canada and Environment Canada. However, the AQHI program would not be possible without the commitment and support of the provinces, municipalities and NGOs. From air quality monitoring to health risk communication and community engagement, local partners are responsible for the vast majority of work related to AQHI implementation. The AQHI provides a number from 1 to 10+ to indicate the level of health risk associated with local air quality. Occasionally, when the amount of air pollution is abnormally high, the number may exceed 10. The AQHI provides a local air quality current value as well as a local air quality maximums forecast for today, tonight and tomorrow and provides associated health advice.

1 2 3 4 5 6 7 8 9 10 +
Risk: Low (1–3) Moderate (4–6) High (7–10) Very high (above 10)

As it is now known that even low levels of air pollution can trigger discomfort for the sensitive population, the index has been developed as a continuum: The higher the number, the greater the health risk and need to take precautions. The index describes the level of health risk associated with this number as 'low', 'moderate', 'high' or 'very high', and suggests steps that can be taken to reduce exposure.[282]

Health risk Air Quality Health Index Health messages[283]
At risk population General population
Low 1–3 Enjoy your usual outdoor activities. Ideal air quality for outdoor activities
Moderate 4–6 Consider reducing or rescheduling strenuous activities outdoors if you are experiencing symptoms. No need to modify your usual outdoor activities unless you experience symptoms such as coughing and throat irritation.
High 7–10 Reduce or reschedule strenuous activities outdoors. Children and the elderly should also take it easy. Consider reducing or rescheduling strenuous activities outdoors if you experience symptoms such as coughing and throat irritation.
Very high Above 10 Avoid strenuous activities outdoors. Children and the elderly should also avoid outdoor physical exertion and should stay indoors. Reduce or reschedule strenuous activities outdoors, especially if you experience symptoms such as coughing and throat irritation.

The measurement is based on the observed relationship of nitrogen dioxide (NO2), ground-level ozone (O3) and particulates (PM2.5) with mortality, from an analysis of several Canadian cities. Significantly, all three of these pollutants can pose health risks, even at low levels of exposure, especially among those with pre-existing health problems.

When developing the AQHI, Health Canada's original analysis of health effects included five major air pollutants: particulates, ozone, and nitrogen dioxide (NO2), as well as sulfur dioxide (SO2), and carbon monoxide (CO). The latter two pollutants provided little information in predicting health effects and were removed from the AQHI formulation.

The AQHI does not measure the effects of odour, pollen, dust, heat or humidity.

Germany

TA Luft is the German air quality regulation.[284]

Governing urban air pollution

In Europe, Council Directive 96/62/EC on ambient air quality assessment and management provides a common strategy against which member states can "set objectives for ambient air quality in order to avoid, prevent or reduce harmful effects on human health and the environment ... and improve air quality where it is unsatisfactory".[285]

In July 2008, in the case Dieter Janecek v. Freistaat Bayern, the European Court of Justice ruled that under this directive[285] citizens have the right to require national authorities to implement a short term action plan that aims to maintain or achieve compliance to air quality limit values.[286][287]

This important case law appears to confirm the role of the EC as centralised regulator to European nation-states as regards air pollution control. It places a supranational legal obligation on the UK to protect its citizens from dangerous levels of air pollution, furthermore superseding national interests with those of the citizen.

In 2010, the European Commission (EC) threatened the UK with legal action against the successive breaching of PM10 limit values.[288] The UK government has identified that if fines are imposed, they could cost the nation upwards of £300 million per year.[289]

In March 2011, the Greater London Built-up Area remained the only UK region in breach of the EC's limit values, and was given three months to implement an emergency action plan aimed at meeting the EU Air Quality Directive.[290] The City of London has dangerous levels of PM10 concentrations, estimated to cause 3000 deaths per year within the city.[291] As well as the threat of EU fines, in 2010 it was threatened with legal action for scrapping the western congestion charge zone, which is claimed to have led to an increase in air pollution levels.[292]

In response to these charges, mayor of London Boris Johnson has criticised the current need for European cities to communicate with Europe through their nation state's central government, arguing that in future "A great city like London" should be permitted to bypass its government and deal directly with the European Commission regarding its air quality action plan.[290]

This can be interpreted as recognition that cities can transcend the traditional national government organisational hierarchy and develop solutions to air pollution using global governance networks, for example through transnational relations. Transnational relations include but are not exclusive to national governments and intergovernmental organisations,[293] allowing sub-national actors including cities and regions to partake in air pollution control as independent actors.

Global city partnerships can be built into networks, for example the C40 Cities Climate Leadership Group, of which London is a member. The C40 is a public 'non-state' network of the world's leading cities that aims to curb their greenhouse emissions.[294] The C40 has been identified as 'governance from the middle' and is an alternative to intergovernmental policy.[295] It has the potential to improve urban air quality as participating cities "exchange information, learn from best practices and consequently mitigate carbon dioxide emissions independently from national government decisions".[294] A criticism of the C40 network is that its exclusive nature limits influence to participating cities and risks drawing resources away from less powerful city and regional actors.

Hotspots

Main page: Physics:Toxic hotspot

Air pollution hotspots are areas where air pollution emissions expose individuals to increased negative health effects.[296] They are particularly common in highly populated, urban areas, where there may be a combination of stationary sources (e.g. industrial facilities) and mobile sources (e.g. cars and trucks) of pollution. Emissions from these sources can cause respiratory disease, childhood asthma,[134] cancer, and other health problems. Fine particulate matter such as diesel soot, which contributes to more than 3.2 million premature deaths around the world each year, is a significant problem. It is very small and can lodge itself within the lungs and enter the bloodstream. Diesel soot is concentrated in densely populated areas, and one in six people in the U.S. live near a diesel pollution hot spot.[297]

External video
AirVisual Earth – realtime map of global wind and air pollution[298]

While air pollution hotspots affect a variety of populations, some groups are more likely to be located in hotspots. Previous studies have shown disparities in exposure to pollution by race and/or income. Hazardous land uses (toxic storage and disposal facilities, manufacturing facilities, major roadways) tend to be located where property values and income levels are low. Low socioeconomic status can be a proxy for other kinds of social vulnerability, including race, a lack of ability to influence regulation and a lack of ability to move to neighborhoods with less environmental pollution. These communities bear a disproportionate burden of environmental pollution and are more likely to face health risks such as cancer or asthma.[299]

Studies show that patterns in race and income disparities not only indicate a higher exposure to pollution but also higher risk of adverse health outcomes.[300] Communities characterized by low socioeconomic status and racial minorities can be more vulnerable to cumulative adverse health impacts resulting from elevated exposure to pollutants than more privileged communities.[300] Blacks and Latinos generally face more pollution than Whites and Asians, and low-income communities bear a higher burden of risk than affluent ones.[299] Racial discrepancies are particularly distinct in suburban areas of the Southern United States and metropolitan areas of the Midwestern and Western United States.[301] Residents in public housing, who are generally low-income and cannot move to healthier neighborhoods, are highly affected by nearby refineries and chemical plants.[302]

Cities

Nitrogen dioxide concentrations as measured from satellite 2002–2004

Air pollution is usually concentrated in densely populated metropolitan areas, especially in developing countries where cities are experiencing rapid growth and environmental regulations are relatively lax or nonexistent. Urbanization leads to a rapid rise in premature mortality due to anthropogenic air pollution in fast-growing tropical cities.[303] However, even populated areas in developed countries attain unhealthy levels of pollution, with Los Angeles and Rome being two examples.[304] Between 2002 and 2011 the incidence of lung cancer in Beijing near doubled. While smoking remains the leading cause of lung cancer in China, the number of smokers is falling while lung cancer rates are rising .[305]

[306]
World's Most Polluted Cities 2020 2020 Average 2019 Average
Hotan, China 110.2 110.1
Ghaziabad, India 106.6 110.2
Bulandshahr, India 98.4 89.4
Bisrakh Jalalpur, India 96.0 -
Bhiwadi, India 95.5 83.4

Tehran was declared the most polluted city in the world on May 24, 2022.[307]

Projections

In a 2019 projection, by 2030 half of the world's pollution emissions could be generated by Africa.[308] Potential contributors to such an outcome include increased burning activities (such as the burning of open waste), traffic, agri-food and chemical industries, sand dust from the Sahara, and overall population growth.

In a 2012 study, by 2050 outdoor air pollution (particulate matter and ground-level ozone) is projected to become the top cause of environmentally related deaths worldwide.[309]

See also

Source

Measurement

Others


References

  1. 1.0 1.1 1.2 "Air pollution" (in en). https://www.who.int/health-topics/air-pollution. 
  2. 2.0 2.1 Manisalidis, Ioannis; Stavropoulou, Elisavet; Stavropoulos, Agathangelos; Bezirtzoglou, Eugenia (2020). "Environmental and Health Impacts of Air Pollution: A Review". Frontiers in Public Health 8: 14. doi:10.3389/fpubh.2020.00014. ISSN 2296-2565. PMID 32154200. 
  3. Howell, Rachel; Pickerill, Jenny (2016). "The Environment and Environmentalism". in Daniels, Peter; Bradshaw, Michael; Shaw, Denis et al.. An Introduction To Human Geography (5th ed.). Pearson. p. 134. ISBN 978-1-292-12939-6. 
  4. Dimitriou, Anastasia; Christidou, Vasilia (2011-09-26), Khallaf, Mohamed, ed., "Causes and Consequences of Air Pollution and Environmental Injustice as Critical Issues for Science and Environmental Education" (in en), The Impact of Air Pollution on Health, Economy, Environment and Agricultural Sources (InTech), doi:10.5772/17654, ISBN 978-953-307-528-0, http://www.intechopen.com/books/the-impact-of-air-pollution-on-health-economy-environment-and-agricultural-sources/causes-and-consequences-of-air-pollution-and-environmental-injustice-as-critical-issues-for-science-, retrieved 2022-05-31 
  5. 5.0 5.1 5.2 5.3 5.4 "7 million premature deaths annually linked to air pollution". WHO. 25 March 2014. https://www.who.int/news/item/25-03-2014-7-million-premature-deaths-annually-linked-to-air-pollution. 
  6. Allen, J. L.; Klocke, C.; Morris-Schaffer, K.; Conrad, K.; Sobolewski, M.; Cory-Slechta, D. A. (June 2017). "Cognitive Effects of Air Pollution Exposures and Potential Mechanistic Underpinnings" (in en). Current Environmental Health Reports 4 (2): 180–191. doi:10.1007/s40572-017-0134-3. PMID 28435996. 
  7. Newbury, Joanne B.; Stewart, Robert; Fisher, Helen L.; Beevers, Sean; Dajnak, David; Broadbent, Matthew; Pritchard, Megan; Shiode, Narushige et al. (2021). "Association between air pollution exposure and mental health service use among individuals with first presentations of psychotic and mood disorders: retrospective cohort study" (in en). The British Journal of Psychiatry 219 (6): 678–685. 2021-08-19. doi:10.1192/bjp.2021.119. ISSN 0007-1250. PMID 35048872. 
  8. 8.0 8.1 Ghosh, Rakesh; Causey, Kate; Burkart, Katrin; Wozniak, Sara; Cohen, Aaron; Brauer, Michael (28 September 2021). "Ambient and household PM2.5 pollution and adverse perinatal outcomes: A meta-regression and analysis of attributable global burden for 204 countries and territories" (in en). PLOS Medicine 18 (9): e1003718. doi:10.1371/journal.pmed.1003718. ISSN 1549-1676. PMID 34582444. 
  9. Stanek, L. W.; Brown, J. S.; Stanek, J.; Gift, J.; Costa, D. L. (2011). "Air Pollution Toxicology—A Brief Review of the Role of the Science in Shaping the Current Understanding of Air Pollution Health Risks". Toxicological Sciences 120: S8–S27. doi:10.1093/toxsci/kfq367. PMID 21147959. https://academic.oup.com/toxsci/article-lookup/doi/10.1093/toxsci/kfq367. Retrieved 2022-11-07. 
  10. Majumder, Nairrita; Kodali, Vamsi; Velayutham, Murugesan; Goldsmith, Travis; Amedro, Jessica; Khramtsov, Valery V.; Erdely, Aaron; Nurkiewicz, Timothy R. et al. (2022). "Aerosol physicochemical determinants of carbon black and ozone inhalation co-exposure induced pulmonary toxicity". Toxicological Sciences 191 (1): 61–78. doi:10.1093/toxsci/kfac113. PMID 36303316. 
  11. 11.0 11.1 11.2 11.3 11.4 11.5 Daniel A. Vallero. "Fundamentals of Air Pollution". Elsevier Academic Press. http://store.elsevier.com/Fundamentals-of-Air-Pollution/Daniel-Vallero/isbn-9780123736154/. 
  12. Lelieveld, J.; Klingmüller, K.; Pozzer, A.; Burnett, R. T.; Haines, A.; Ramanathan, V. (25 March 2019). "Effects of fossil fuel and total anthropogenic emission removal on public health and climate". Proceedings of the National Academy of Sciences of the United States of America 116 (15): 7192–7197. doi:10.1073/pnas.1819989116. PMID 30910976. Bibcode2019PNAS..116.7192L. 
  13. "Fine Particulate Matter Map Shows Premature Mortality Due to Air Pollution - SpaceRef". 19 September 2013. http://spaceref.com/earth/fine-particulate-matter-map-shows-premature-mortality-due-to-air-polution.html. 
  14. Silva, Raquel A; West, J Jason; Zhang, Yuqiang; Anenberg, Susan C; Lamarque, Jean-François; Shindell, Drew T; Collins, William J; Dalsoren, Stig et al. (2013). "Global premature mortality due to anthropogenic outdoor air pollution and the contribution of past climate change". Environmental Research Letters 8 (3): 034005. doi:10.1088/1748-9326/8/3/034005. Bibcode2013ERL.....8c4005S. 
  15. 15.0 15.1 Lelieveld, Jos; Pozzer, Andrea; Pöschl, Ulrich; Fnais, Mohammed; Haines, Andy; Münzel, Thomas (1 September 2020). "Loss of life expectancy from air pollution compared to other risk factors: a worldwide perspective". Cardiovascular Research 116 (11): 1910–1917. doi:10.1093/cvr/cvaa025. ISSN 0008-6363. PMID 32123898. 
  16. "Energy and Air Pollution". http://www.iea.org/publications/freepublications/publication/WorldEnergyOutlookSpecialReport2016EnergyandAirPollution.pdf. 
  17. "Study Links 6.5 Million Deaths Each Year to Air Pollution". The New York Times. 26 June 2016. https://www.nytimes.com/2016/06/27/business/energy-environment/study-links-6-5-million-deaths-each-year-to-air-pollution.html. 
  18. 18.0 18.1 18.2 Fuller, Richard; Landrigan, Philip J; Balakrishnan, Kalpana; Bathan, Glynda; Bose-O'Reilly, Stephan; Brauer, Michael; Caravanos, Jack; Chiles, Tom et al. (June 2022). "Pollution and health: a progress update". The Lancet Planetary Health 6 (6): e535–e547. doi:10.1016/S2542-5196(22)00090-0. PMID 35594895. 
  19. "Reports". WorstPolluted.org. http://www.worstpolluted.org/. 
  20. 20.0 20.1 "9 out of 10 people worldwide breathe polluted air, but more countries are taking action" (in en). World Health Organization. 2 May 2018. https://www.who.int/news/item/02-05-2018-9-out-of-10-people-worldwide-breathe-polluted-air-but-more-countries-are-taking-action. 
  21. "Cheap air pollution monitors help plot your walk" (in en). https://www.eib.org/en/stories/air-pollution-monitor. 
  22. "Assessing the risks to health from air pollution" (in en). European Environment Agency. https://www.eea.europa.eu/publications/assessing-the-risks-to-health. 
  23. 23.0 23.1 23.2 World Bank; Institute for Health Metrics and Evaluation at University of Washington – Seattle (2016). The Cost of Air Pollution: Strengthening the Economic Case for Action. Washington, D.C.: The World Bank. p. xii. http://documents.worldbank.org/curated/en/781521473177013155/pdf/108141-REVISED-Cost-of-PollutionWebCORRECTEDfile.pdf. 
  24. 24.0 24.1 24.2 McCauley, Lauren (8 September 2016). "Making Case for Clean Air, World Bank Says Pollution Cost Global Economy $5 Trillion". Common Dreams. https://www.commondreams.org/news/2016/09/08/making-case-clean-air-world-bank-says-pollution-cost-global-economy-5-trillion. 
  25. 25.0 25.1 "The Rising Cost of Smog". Fortune: 15. 1 February 2018. ISSN 0015-8259. 
  26. Batool, Rubeena; Zaman, Khalid; Khurshid, Muhammad Adnan; Sheikh, Salman Masood; Aamir, Alamzeb; Shoukry, Alaa Mohamd; Sharkawy, Mohamed A.; Aldeek, Fares et al. (October 2019). "Economics of death and dying: a critical evaluation of environmental damages and healthcare reforms across the globe". Environmental Science and Pollution Research International 26 (29): 29799–29809. doi:10.1007/s11356-019-06159-x. ISSN 1614-7499. PMID 31407261. Bibcode2019ESPR...2629799B. 
  27. Bherwani, Hemant; Nair, Moorthy; Musugu, Kavya; Gautam, Sneha; Gupta, Ankit; Kapley, Atya; Kumar, Rakesh (10 June 2020). "Valuation of air pollution externalities: comparative assessment of economic damage and emission reduction under COVID-19 lockdown". Air Quality, Atmosphere & Health 13 (6): 683–694. doi:10.1007/s11869-020-00845-3. ISSN 1873-9318. PMID 32837611. Bibcode2020AQAH...13..683B. 
  28. 28.0 28.1 Fensterstock, J. C.; Kurtzweg, J. A.; Ozolins, G. (1971). "Reduction of Air Pollution Potential through Environmental Planning". Journal of the Air Pollution Control Association 21 (7): 395–399. doi:10.1080/00022470.1971.10469547. PMID 5148260. 
  29. 29.0 29.1 Fensterstock, Ketcham and Walsh, The Relationship of Land Use and Transportation Planning to Air Quality Management, Ed. George Hagevik, May 1972.
  30. US EPA, OCSPP (2014-09-22). "Pollution Prevention Law and Policies" (in en). https://www.epa.gov/p2/pollution-prevention-law-and-policies. 
  31. Frieden, Thomas R. (January 2014). "Six Components Necessary for Effective Public Health Program Implementation" (in en). American Journal of Public Health 104 (1): 17–22. doi:10.2105/AJPH.2013.301608. ISSN 0090-0036. PMID 24228653. 
  32. Environment, U. N. (2018-10-29). "About Montreal Protocol" (in en). http://www.unep.org/ozonaction/who-we-are/about-montreal-protocol. 
  33. "The Montreal Protocol on Substances That Deplete the Ozone Layer" (in en-US). https://www.state.gov/key-topics-office-of-environmental-quality-and-transboundary-issues/the-montreal-protocol-on-substances-that-deplete-the-ozone-layer/. 
  34. "Protocol On Further Reduction Of Sulphur Emissions To The Convention On Long-Range Transboundary Air Pollution | International Environmental Agreements (IEA) Database Project" (in en). https://iea.uoregon.edu/treaty-text/3186. 
  35. Nations, United. "ClimateChange" (in en). https://www.un.org/en/climatechange. 
  36. "Climate change" (in en). World Health Organization. https://www.who.int/health-topics/climate-change. 
  37. "Global Climate Agreements: Successes and Failures" (in en). https://www.cfr.org/backgrounder/paris-global-climate-change-agreements. 
  38. Perera, Frederica (2017-12-23). "Pollution from Fossil-Fuel Combustion is the Leading Environmental Threat to Global Pediatric Health and Equity: Solutions Exist" (in en). International Journal of Environmental Research and Public Health 15 (1): 16. doi:10.3390/ijerph15010016. ISSN 1660-4601. PMID 29295510. 
  39. "Mapping methane emissions on a global scale" (in en). ESA. https://www.esa.int/Applications/Observing_the_Earth/Copernicus/Sentinel-5P/Mapping_methane_emissions_on_a_global_scale. 
  40. "Climate change: Satellites map huge methane plumes from oil and gas". BBC News. 4 February 2022. https://www.bbc.com/news/science-environment-60203683. 
  41. "Cracking down on methane 'ultra emitters' is a quick way to combat climate change, researchers find". The Washington Post. https://www.washingtonpost.com/climate-environment/2022/02/03/cracking-down-methane-ultra-emitters-is-quick-way-combat-climate-change-researchers-find/. 
  42. Lauvaux, T.; Giron, C.; Mazzolini, M.; d’Aspremont, A.; Duren, R.; Cusworth, D.; Shindell, D.; Ciais, P. (4 February 2022). "Global assessment of oil and gas methane ultra-emitters". Science 375 (6580): 557–561. doi:10.1126/science.abj4351. ISSN 0036-8075. PMID 35113691. Bibcode2022Sci...375..557L. https://www.science.org/doi/10.1126/science.abj4351. 
  43. Rentschler, Jun; Leonova, Nadezda (2023). "Global air pollution exposure and poverty". Nature Communications 14 (1): 4432. doi:10.1038/s41467-023-39797-4. PMID 37481598. Bibcode2023NatCo..14.4432R. 
  44. Pennise, David; Smith, Kirk. "Biomass Pollution Basics". World Health Organization. https://www.who.int/indoorair/interventions/antiguamod21.pdf. 
  45. "Indoor air pollution and household energy". WHO and UNEP. 2011. https://www.who.int/heli/risks/indoorair/indoorair/en/index.html. 
  46. Hawkes, N. (22 May 2015). "Air pollution in UK: the public health problem that won't go away". BMJ 350 (may22 1): h2757. doi:10.1136/bmj.h2757. PMID 26001592. 
  47. "Wood burning heaters and your health - Fact sheets". https://www.health.nsw.gov.au/environment/factsheets/Pages/wood-smoke.aspx. 
  48. Tsiodra, Irini; Grivas, Georgios; Tavernaraki, Kalliopi; Bougiatioti, Aikaterini; Apostolaki, Maria; Paraskevopoulou, Despina; Gogou, Alexandra; Parinos, Constantine et al. (7 December 2021). "Annual exposure to polycyclic aromatic hydrocarbons in urban environments linked to wintertime wood-burning episodes" (in English). Atmospheric Chemistry and Physics 21 (23): 17865–17883. doi:10.5194/acp-21-17865-2021. ISSN 1680-7316. Bibcode2021ACP....2117865T. 
  49. Nace, Trevor. "China Shuts Down Tens Of Thousands Of Factories In Widespread Pollution Crackdown". Forbes. https://www.forbes.com/sites/trevornace/2017/10/24/china-shuts-down-tens-of-thousands-of-factories-in-widespread-pollution-crackdown/. ""... it is estimated that 40 percent of all China's factories have been shut down at some point in order to be inspected... [and] over 80,000 factories have been hit with fines and criminal offenses as a result of their emissions."" 
  50. Huo, Hong; Zhang, Qiang; Guan, Dabo; Su, Xin; Zhao, Hongyan; He, Kebin (16 December 2014). "Examining Air Pollution in China Using Production- And Consumption-Based Emissions Accounting Approaches". Environmental Science & Technology 48 (24): 14139–14147. doi:10.1021/es503959t. ISSN 0013-936X. PMID 25401750. Bibcode2014EnST...4814139H. 
  51. Huo, Hong; Zhang, Qiang; Guan, Dabo; Su, Xin; Zhao, Hongyan; He, Kebin (2014-12-16). "Examining Air Pollution in China Using Production- And Consumption-Based Emissions Accounting Approaches" (in en). Environmental Science & Technology 48 (24): 14139–14147. doi:10.1021/es503959t. ISSN 0013-936X. PMID 25401750. Bibcode2014EnST...4814139H. https://pubs.acs.org/doi/10.1021/es503959t. 
  52. "EMEP/EEA air pollutant emission inventory guidebook 2019". https://www.eea.europa.eu/publications/emep-eea-guidebook-2019/part-b-sectoral-guidance-chapters/2-industrial-processes/2-a-mineral-products/2-a-5-b-construction. 
  53. "Particulate Matter (PM), US EPA". 19 April 2016. https://www.epa.gov/pm-pollution/particulate-matter-pm-basics. 
  54. "Health crisis: Up to a billion tons of waste potentially burned in the open every year" (in en). phys.org. https://phys.org/news/2021-01-health-crisis-billion-tons-potentially.html. 
  55. Cook, E.; Velis, C. A. (6 January 2021). "Global Review on Safer End of Engineered Life" (in en). Global Review on Safer End of Engineered Life. http://eprints.whiterose.ac.uk/169766/. Retrieved 13 February 2021. 
  56. "Combustion Pollutants in Your Home - Guidelines". California Air Resources Board. https://ww2.arb.ca.gov/resources/documents/combustion-pollutants-your-home-guidelines. ""... most furnaces, wood stoves, fireplaces, gas water heaters, and gas clothes dryers, usually vent (exhaust) the combustion pollutants directly to the outdoors. However, if the vent system is not properly designed, installed, and maintained, indoor pollutants can build up quickly inside the home." 
  57. "Overview of Air Pollution from Transportation". US Environmental Protection Agency. 15 December 2021. https://www.epa.gov/transportation-air-pollution-and-climate-change/overview-air-pollution-transportation. 
  58. Ryan, Robert G.; Marais, Eloise A.; Balhatchet, Chloe J.; Eastham, Sebastian D. (June 2022). "Impact of Rocket Launch and Space Debris Air Pollutant Emissions on Stratospheric Ozone and Global Climate" (in en). Earth's Future 10 (6): e2021EF002612. doi:10.1029/2021EF002612. ISSN 2328-4277. PMID 35865359. Bibcode2022EaFut..1002612R. 
  59. Yeung, Jessie. "Microplastics in our air 'spiral the globe' in a cycle of pollution, study finds". https://edition.cnn.com/2021/04/13/world/atmospheric-plastics-study-intl-hnk-scli-scn/index.html. 
  60. "The environmental impacts of cars explained" (in en). Environment (National Geographic). 4 September 2019. https://www.nationalgeographic.com/environment/article/environmental-impact. 
  61. "NASA GISS: NASA News & Feature Releases:Road Transportation Emerges as Key Driver of Warming" (in en). https://www.giss.nasa.gov/research/news/20100218a/. 
  62. "Car Emissions & Global Warming | Union of Concerned Scientists" (in en). https://www.ucsusa.org/resources/car-emissions-global-warming. 
  63. "NASA's AIRS Maps Carbon Monoxide from Brazil Fires". https://www.jpl.nasa.gov/images/pia23356-nasas-airs-maps-carbon-monoxide-from-brazil-fires. 
  64. Harper, Ashleigh R.; Doerr, Stefan H.; Santin, Cristina; Froyd, Cynthia A.; Sinnadurai, Paul (2018-05-15). "Prescribed fire and its impacts on ecosystem services in the UK" (in en). Science of the Total Environment 624: 691–703. doi:10.1016/j.scitotenv.2017.12.161. ISSN 0048-9697. PMID 29272838. Bibcode2018ScTEn.624..691H. https://www.sciencedirect.com/science/article/pii/S0048969717335878. 
  65. George Neary, Daniel; McMichael Leonard, Jackson (2020-04-08), Missiakô Kindomihou, Valentin, ed., "Effects of Fire on Grassland Soils and Water: A Review" (in en), Grasses and Grassland Aspects (IntechOpen), doi:10.5772/intechopen.90747, ISBN 978-1-78984-949-3, https://www.intechopen.com/books/grasses-and-grassland-aspects/effects-of-fire-on-grassland-soils-and-water-a-review, retrieved 2022-06-07 
  66. Husseini, Rikiatu; Aboah, Daniel T.; Issifu, Hamza (2020-03-01). "Fire control systems in forest reserves: An assessment of three forest districts in the Northern region, Ghana" (in en). Scientific African 7: e00245. doi:10.1016/j.sciaf.2019.e00245. ISSN 2468-2276. Bibcode2020SciAf...700245H. https://www.sciencedirect.com/science/article/pii/S2468227619308063. 
  67. Reyes, O.; Casal, M. (November 2004). "Effects of forest fire ash on germination and early growth of four pinus species" (in en). Plant Ecology 175 (1): 81–89. doi:10.1023/B:VEGE.0000048089.25497.0c. ISSN 1385-0237. Bibcode2004PlEco.175...81R. http://link.springer.com/10.1023/B:VEGE.0000048089.25497.0c. 
  68. Chatterjee, Rhitu (15 February 2018). "Wall Paint, Perfumes and Cleaning Agents Are Polluting Our Air". NPR. https://www.npr.org/sections/thetwo-way/2018/02/15/585886321/your-wall-paint-perfumes-and-cleaning-agents-are-polluting-our-air. 
  69. "Basic Information about Landfill Gas". 15 April 2016. https://www.epa.gov/lmop/basic-information-about-landfill-gas. "Landfill gas (LFG) is a natural byproduct of the decomposition of organic material in landfills. LFG is composed of roughly 50 percent methane..." 
  70. "Open waste burning prevention | Climate & Clean Air Coalition" (in en). 2023-09-07. https://www.ccacoalition.org/projects/open-waste-burning-prevention. 
  71. Hafemeister, David (2016), "Biological and Chemical Weapons" (in en), Nuclear Proliferation and Terrorism in the Post-9/11 World, Cham: Springer International Publishing, pp. 337–351, doi:10.1007/978-3-319-25367-1_15, ISBN 978-3-319-25365-7 
  72. Sun, Feifei; Dai, Yun; Yu, Xiaohua (December 2017). "Air pollution, food production and food security: A review from the perspective of food system". Journal of Integrative Agriculture 16 (12): 2945–2962. doi:10.1016/S2095-3119(17)61814-8. 
  73. 73.0 73.1 Lelieveld, J.; Evans, J. S.; Fnais, M.; Giannadaki, D.; Pozzer, A. (September 2015). "The contribution of outdoor air pollution sources to premature mortality on a global scale" (in en). Nature 525 (7569): 367–371. doi:10.1038/nature15371. ISSN 1476-4687. PMID 26381985. Bibcode2015Natur.525..367L. "Whereas in much of the USA and in a few other countries emissions from traffic and power generation are important, in eastern USA, Europe, Russia and East Asia agricultural emissions make the largest relative contribution to PM2.5, with the estimate of overall health impact depending on assumptions regarding particle toxicity.". 
  74. Diep, Francie (31 January 2018). "California's Farms Are an Even Larger Source of Air Pollution Than We Thought". Pacific Standard. https://psmag.com/environment/californias-farms-are-an-even-larger-source-of-air-pollution-than-we-thought. 
  75. Nemecek, T.; Poore, J. (1 June 2018). "Reducing food's environmental impacts through producers and consumers". Science 360 (6392): 987–992. doi:10.1126/science.aaq0216. ISSN 0036-8075. PMID 29853680. Bibcode2018Sci...360..987P. 
  76. "Education Data, Visualizations & Graphics on particulate pollution.". https://www.cleanairresources.com/data. 
  77. Goldstein, Allen H.; Koven, Charles D.; Heald, Colette L.; Fung, Inez Y. (5 May 2009). "Biogenic carbon and anthropogenic pollutants combine to form a cooling haze over the southeastern United States". Proceedings of the National Academy of Sciences 106 (22): 8835–40. doi:10.1073/pnas.0904128106. PMID 19451635. Bibcode2009PNAS..106.8835G. 
  78. Fischetti, Mark (2014). "Trees That Pollute". Scientific American 310 (6): 14. doi:10.1038/scientificamerican0614-14. PMID 25004561. Bibcode2014SciAm.310f..14F. 
  79. "Volcanic Pollution |" (in en-CAC). https://intlpollution.commons.gc.cuny.edu/volcanic-pollution/. 
  80. "Air Pollution Emissions" (in en). 2016. https://www3.epa.gov/airquality/emission.html. 
  81. Environment and Climate Change Canada (14 June 2010). "Air pollutant emissions". https://www.canada.ca/en/environment-climate-change/services/environmental-indicators/air-pollutant-emissions.html. 
  82. Manisalidis, Ioannis; Stavropoulou, Elisavet; Stavropoulos, Agathangelos; Bezirtzoglou, Eugenia (2020-02-20). "Environmental and Health Impacts of Air Pollution: A Review". Frontiers in Public Health 8: 14. doi:10.3389/fpubh.2020.00014. ISSN 2296-2565. PMID 32154200. 
  83. "AP 42, Volume I". http://www.epa.gov/ttn/chief/ap42/index.html. 
  84. "United Kingdom's emission factor database". http://www.naei.org.uk/emissions/index.php. 
  85. "EMEP/EEA air pollutant emission inventory guidebook—2009". European Environmental Agency. 19 June 2009. http://www.eea.europa.eu/publications/emep-eea-emission-inventory-guidebook-2009. 
  86. "Environmental Pollution". 16 December 2011. http://www.theenvironmentalblog.org/environmental-issues/environmental-pollution/. 
  87. "Revised 1996 IPCC Guidelines for National Greenhouse Gas Inventories (reference manual)". http://www.ipcc-nggip.iges.or.jp/public/gl/invs6.htm. 
  88. US EPA, OAR (2015-12-10). "Managing Air Quality - Air Pollutant Types" (in en). US Environmental Protection Agency. https://www.epa.gov/air-quality-management-process/managing-air-quality-air-pollutant-types. 
  89. Aerosols: An Industrial and Environmental Science. Elsevier. 2012. p. 1. ISBN 978-0-323-14251-9. https://books.google.com/books?id=OJxPHYnC9b8C. 
  90. Carrington, Damian (2021-11-04). "Ammonia from farms behind 60% of UK particulate air pollution – study" (in en). The Guardian. https://www.theguardian.com/environment/2021/nov/04/ammonia-from-farms-behind-60-of-uk-particulate-air-pollution-study. 
  91. "The Effect of Changing Background Emissions on External Cost Estimates for Secondary Particulates". Open environmental sciences. 2008. https://www.researchgate.net/publication/250144316. 
  92. Johnson, Keith (18 April 2009). "How Carbon Dioxide Became a 'Pollutant'". https://www.wsj.com/articles/SB124001537515830975. 
  93. "Carbon dioxide". U.S. Department of Health & Human Services. 30 October 2019. https://www.cdc.gov/niosh/npg/npgd0103.html. 
  94. 94.0 94.1 "General hazards of Carbon Dioxide". UK Government. https://www.hse.gov.uk/carboncapture/carbondioxide.htm. "For over a century CO
    2
    has been recognised as a workplace hazard at high concentrations. CO
    2
    is naturally present in the air we breathe at a concentration of about 0.037% and is not harmful to health at low concentrations."
     
  95. Air Quality Guidelines Global Update 2005: Particulate matter, ozone, nitrogen dioxide and sulfur dioxide. Copenhagen, Denmark: World Health Organization. 2006. p. 12. ISBN 92-890-2192-6. ""Some pollutants, and especially those associated with greenhouse warming effects (carbon dioxide, nitrous oxide and methane)..."" 
  96. Vaidyanathan, Gayathri. "The Worst Climate Pollution Is Carbon Dioxide". Scientific American. https://www.scientificamerican.com/article/the-worst-climate-pollution-is-carbon-dioxide/. 
  97. Barbalace, Roberta C. (7 November 2006). "CO
    2
    Pollution and Global Warming: When does carbon dioxide become a pollutant?"
    . https://environmentalchemistry.com/yogi/environmental/200611CO2globalwarming.html.
     
  98. Friedman, Lisa (22 August 2022). "Democrats Designed the Climate Law to Be a Game Changer. Here's How.". The New York Times. https://www.nytimes.com/2022/08/22/climate/epa-supreme-court-pollution.html. 
  99. "Graphic: The relentless rise of carbon dioxide". NASA. https://climate.nasa.gov/climate_resources/24/. 
  100. "How much of U.S. carbon dioxide emissions are associated with electricity generation?". http://www.eia.gov/tools/faqs/faq.cfm?id=77&t=11. 
  101. "Full Mauna Loa CO
    2
    record"
    . https://www.esrl.noaa.gov/gmd/ccgg/trends/full.html.
     
  102. "OECD Test Guidelines for Chemicals". https://www.oecd.org/chemicalsafety/testing/oecdguidelinesforthetestingofchemicals.htm. 
  103. "The Strange Lake Nyos CO
    2
    Gas Disaster: Impacts and The Displacement and Return of Affected Communities"
    . https://www.massey.ac.nz/~trauma/issues/2011-1/fomine.htm.
     
  104. "Carbon Monoxide Poisoning – NHS". 17 October 2017. https://www.nhs.uk/conditions/carbon-monoxide-poisoning/. 
  105. US EPA, OAR (2017-06-05). "Basic Ozone Layer Science" (in en). US Environmental Protection Agency. https://www.epa.gov/ozone-layer-protection/basic-ozone-layer-science. 
  106. "Chlorofluorocarbons (CFCs) are heavier than air, so how do scientists suppose that these chemicals reach the altitude of the ozone layer to adversely affect it?" (in en). https://www.scientificamerican.com/article/chlorofluorocarbons-cfcs/. 
  107. "What is Particulate Matter? | Urban Environmental Program in New England" (in en). March 29, 2022. https://www3.epa.gov/region1/eco/uep/particulatematter.html. 
  108. Munsif, Rabia; Zubair, Muhammad; Aziz, Ayesha; Nadeem Zafar, Muhammad (2021-01-07), Viskup, Richard, ed., "Industrial Air Emission Pollution: Potential Sources and Sustainable Mitigation" (in en), Environmental Emissions (IntechOpen), doi:10.5772/intechopen.93104, ISBN 978-1-83968-510-1, https://www.intechopen.com/books/environmental-emissions/industrial-air-emission-pollution-potential-sources-and-sustainable-mitigation, retrieved 2022-06-07 
  109. "Evidence growing of air pollution's link to heart disease, death". https://www.newsroom.heart.org/index.php?s=43&item=1029.  // American Heart Association. 10 May 2010
  110. Balmes, J.R.; Fine, J.M.; Sheppard, D. (1987). "Symptomatic bronchoconstriction after short-term inhalation of sulfur dioxide". American Review of Respiratory Disease 136 (5): 1117–21. doi:10.1164/ajrccm/136.5.1117. PMID 3674573. 
  111. Singh, Ritu; Kumar, Sanjeev; Karmakar, Susmita; Siddiqui, Arif J.; Mathur, Ankita; Adnan, Mohd.; Rajput, Vishnu D.; Rani, Anita et al. (2021). "2: Causes, Consequences, and Control of Persistent Organic Pollutants". in Kumar, Narendra; Shukla, Vertika. Persistent Organic Pollutants in the Environment: Origin and Role. CRC Press. pp. 31–54. ISBN 9781003053170. https://books.google.com/books?id=NiRAEAAAQBAJ. Retrieved 11 June 2022. 
  112. "Newly detected air pollutant mimics damaging effects of cigarette smoke". http://www.physorg.com/pdf138201201.pdf. 
  113. "Infant Inhalation Of Ultra-fine Air Pollution Linked To Adult Lung Disease". 23 July 2009. https://www.sciencedaily.com/releases/2009/07/090722123751.htm. 
  114. Kim, Ki-Hyun; Jahan, Shamin Ara; Kabir, Ehsanul; Brown, Richard J. C. (2013-10-01). "A review of airborne polycyclic aromatic hydrocarbons (PAHs) and their human health effects" (in en). Environment International 60: 71–80. doi:10.1016/j.envint.2013.07.019. ISSN 0160-4120. PMID 24013021. https://www.sciencedirect.com/science/article/pii/S0160412013001633. 
  115. "Technical Overview of Volatile Organic Compounds". 14 March 2023. https://www.epa.gov/indoor-air-quality-iaq/technical-overview-volatile-organic-compounds. 
  116. (in en) Read "Rethinking the Ozone Problem in Urban and Regional Air Pollution" at NAP.edu. 1991. doi:10.17226/1889. ISBN 978-0-309-04631-2. https://www.nap.edu/read/1889/chapter/8. 
  117. "ESS Topic 6.3: Photochemical Smog" (in en). https://www.mrgscience.com/ess-topic-63-photochemical-smog.html. 
  118. Acharya, Bishnu (2018-01-01), Basu, Prabir, ed., "Chapter 10 - Cleaning of Product Gas of Gasification" (in en), Biomass Gasification, Pyrolysis and Torrefaction (Third Edition) (Academic Press): pp. 373–391, ISBN 978-0-12-812992-0, https://www.sciencedirect.com/science/article/pii/B9780128129920000108, retrieved 2022-06-07 
  119. "smog | National Geographic Society". National Geographic. https://education.nationalgeographic.org/resource/smog/. 
  120. "Hazardous Air Pollutants". 9 February 2023. https://www.epa.gov/haps. 
  121. "Air quality standards". https://www.eea.europa.eu/themes/air/air-quality-concentrations/air-quality-standards. 
  122. "Air pollution exposure in cities". https://www.eea.europa.eu/media/infographics/air-pollution-exposure-in-cities/view. 
  123. Dons, E. (2011). "Impact of time-activity patterns on personal exposure to black carbon". Atmospheric Environment 45 (21): 3594–3602. doi:10.1016/j.atmosenv.2011.03.064. Bibcode2011AtmEn..45.3594D. 
  124. Dons, E. (2019). "Transport most likely to cause air pollution peak exposures in everyday life: Evidence from over 2000 days of personal monitoring". Atmospheric Environment 213: 424–432. doi:10.1016/j.atmosenv.2019.06.035. Bibcode2019AtmEn.213..424D. 
  125. Carrington, Damian (2021-09-22). "WHO slashes guideline limits on air pollution from fossil fuels" (in en). https://www.theguardian.com/environment/2021/sep/22/who-cuts-guideline-limits-on-air-pollution-from-fossil-fuels. 
  126. "Most of the World Breathes Unsafe Air, Taking More Than 2 Years Off Global Life Expectancy" (in en). 2022-06-14. https://aqli.epic.uchicago.edu/news/most-of-the-world-breathes-unsafe-air-taking-more-than-2-years-off-global-life-expectancy/. 
  127. 127.0 127.1 Duflo, Esther; Greenstone, Michael; Hanna, Rema (26 November 2008). "Indoor air pollution, health and economic well-being". S.A.P.I.EN.S 1 (1). http://sapiens.revues.org/index130.html. Retrieved 29 August 2010. 
  128. 128.0 128.1 "Improved Clean Cookstoves" (in en). 7 February 2020. https://www.drawdown.org/solutions/improved-clean-cookstoves. 
  129. Twilley, Nicola (1 April 2019). "The Hidden Air Pollution in Our Homes". The New Yorker. https://www.newyorker.com/magazine/2019/04/08/the-hidden-air-pollution-in-our-homes. 
  130. "Bucknell tent death: Hannah Thomas-Jones died from carbon monoxide poisoning". BBC News. 17 January 2013. https://www.bbc.co.uk/news/uk-england-21059594. 
  131. "Chapter 6.2. Asbestos. Air quality guidelines, Second edition.". http://www.euro.who.int/__data/assets/pdf_file/0015/123072/AQG2ndEd_6_2_asbestos.PDF. 
  132. "Long-Term Exposure to Low Levels of Air Pollution Increases Risk of Heart and Lung Disease". 22 February 2021. https://www.sciencedaily.com/releases/2021/02/210222082622.htm. 
  133. "EU says one in eight deaths is linked to pollution". BBC News. 8 September 202. https://www.bbc.com/news/world-europe-54071380. 
  134. 134.0 134.1 Carrington, Damian (2021-05-18). "Air pollution linked to 'huge' rise in child asthma GP visits" (in en). The Guardian. http://www.theguardian.com/environment/2021/may/18/air-pollution-linked-to-huge-rise-in-child-asthma-gp-visits. 
  135. "Air quality and health". World Health Organization. https://www.who.int/mediacentre/factsheets/fs313/en/index.html. 
  136. US EPA, OMS (2013-02-22). "Regulatory and Guidance Information by Topic: Air" (in en). https://www.epa.gov/regulatory-information-topic/regulatory-and-guidance-information-topic-air. 
  137. Majumder, Nairrita; Kodali, Vamsi; Velayutham, Murugesan; Goldsmith, Travis; Amedro, Jessica; Khramtsov, Valery V.; Erdely, Aaron; Nurkiewicz, Timothy R. et al. (2022). "Aerosol physicochemical determinants of carbon black and ozone inhalation co-exposure induced pulmonary toxicity". Toxicological Sciences 191 (1): 61–78. doi:10.1093/toxsci/kfac113. PMID 36303316. 
  138. Kampa, Marilena; Castanas, Elias (2008-01-01). "Human health effects of air pollution" (in en). Environmental Pollution. Proceedings of the 4th International Workshop on Biomonitoring of Atmospheric Pollution (With Emphasis on Trace Elements) 151 (2): 362–367. doi:10.1016/j.envpol.2007.06.012. ISSN 0269-7491. PMID 17646040. https://www.sciencedirect.com/science/article/pii/S0269749107002849. 
  139. Dovjak, Mateja; Kukec, Andreja (2019). "Health Outcomes Related to Built Environments". Creating Healthy and Sustainable Buildings. Switzerland: Springer International Publishing. pp. 43–82. doi:10.1007/978-3-030-19412-3_2. ISBN 978-3-030-19411-6. OCLC 1285508857. 
  140. Ritchie, Hannah; Roser, Max (2021). "What are the safest and cleanest sources of energy?". Our World in Data. https://ourworldindata.org/safest-sources-of-energy.  Data sources: Markandya & Wilkinson (2007); UNSCEAR (2008; 2018); Sovacool et al. (2016); IPCC AR5 (2014); Pehl et al. (2017); Ember Energy (2021).
  141. 141.0 141.1 Carrington, Damian (12 March 2019). "Air pollution deaths are double previous estimates, finds research". The Guardian. https://www.theguardian.com/environment/2019/mar/12/air-pollution-deaths-are-double-previous-estimates-finds-research. 
  142. Dickie, Gloria (18 May 2022). "Pollution killing 9 million people a year, Africa hardest hit - study" (in en). Reuters. https://www.reuters.com/business/environment/pollution-killing-9-million-people-year-africa-hardest-hit-study-2022-05-17/. 
  143. Huang, Yuh-Chin T. (October 2014). "Outdoor air pollution: a global perspective". Journal of Occupational and Environmental Medicine 56 (Suppl 10): S3–7. doi:10.1097/JOM.0000000000000240. ISSN 1536-5948. PMID 25285972. 
  144. "Air pollution". https://www.who.int/ceh/risks/cehair/en/. 
  145. 145.0 145.1 "Ambient (outdoor) air pollution" (in en). www.who.int (World Health Organization). https://www.who.int/news-room/fact-sheets/detail/ambient-(outdoor)-air-quality-and-health. 
  146. Baccarelli, Andrea A.; Hales, Nick; Burnett, Richard T.; Jerrett, Michael; Mix, Carter; Dockery, Douglas W.; Pope, C. Arden (1 November 2016). "Particulate Air Pollution, Exceptional Aging, and Rates of Centenarians: A Nationwide Analysis of the United States, 1980–2010". Environmental Health Perspectives 124 (11): 1744–1750. doi:10.1289/EHP197. PMID 27138440. 
  147. Mailloux, Nicholas A.; Abel, David W.; Holloway, Tracey; Patz, Jonathan A. (16 May 2022). "Nationwide and Regional PM2.5-Related Air Quality Health Benefits From the Removal of Energy-Related Emissions in the United States". GeoHealth 6 (5): e2022GH000603. doi:10.1029/2022GH000603. PMID 35599962. 
  148. Harris, Gardiner (2014-01-25). "Beijing's Bad Air Would Be Step Up for Smoggy Delhi" (in en-US). The New York Times. ISSN 0362-4331. https://www.nytimes.com/2014/01/26/world/asia/beijings-air-would-be-step-up-for-smoggy-delhi.html. 
  149. Owusu, Phebe Asantewaa; Sarkodie, Samuel Asumadu (2020-11-10). "Global estimation of mortality, disability-adjusted life years and welfare cost from exposure to ambient air pollution" (in en). Science of the Total Environment 742: 140636. doi:10.1016/j.scitotenv.2020.140636. ISSN 0048-9697. PMID 32721745. Bibcode2020ScTEn.742n0636O. https://www.sciencedirect.com/science/article/pii/S0048969720341589. 
  150. "Lancet study: Pollution killed 2.3 million Indians in 2019" (in en-GB). BBC News. 2022-05-18. https://www.bbc.com/news/world-asia-india-61489488. 
  151. Mr Chen's claim was made in The Lancet (December 2013 issue) and reported in The Daily Telegraph 8 January 2014 p. 15 'Air pollution killing up to 500,000 Chinese each year, admits former health minister.
  152. "Study links traffic pollution to thousands of deaths". The Guardian (London, UK). 15 April 2008. https://www.theguardian.com/society/2008/apr/15/health. 
  153. 153.0 153.1 "Car emissions: taking tests out of the lab and onto the road – News". European Parliament. 25 February 2016. http://www.europarl.europa.eu/news/en/news-room/20160222STO15305/Car-emissions-taking-tests-out-of-the-lab-and-onto-the-road. 
  154. "Complete Guide To The 'Toxin Tax' For Diesel Cars". https://motorway.co.uk/guides/diesel-car-toxin-tax. 
  155. "Air pollution causes early deaths". BBC. 21 February 2005. http://news.bbc.co.uk/2/hi/health/4283295.stm. 
  156. Tankersley, Jim (8 January 2010). "EPA proposes nation's strictest smog limits ever". Los Angeles Times. http://articles.latimes.com/2010/jan/08/nation/la-na-epa-smog-rules8-2010jan08. 
  157. "EPA slideshow". http://yosemite.epa.gov/sab/sabproduct.nsf/0E6B12C5232316558525783400611BE6/$File/ALA+slides.pdf. 
  158. "EPA Strengthens Ozone Standards to Protect Public Health/Science-based standards to reduce sick days, asthma attacks, emergency room visits, greatly outweigh costs (10/1/2015)". https://yosemite.epa.gov/opa/admpress.nsf/931381dfcd9a5c308525779700424ccd/ffe8a2d2a59797b385257ed000724bf0!OpenDocument. 
  159. Grossni, Mark (13 November 2008). "Human cost of valley's dirty air: $6.3 billion". Sacramento Bee. http://www.sacbee.com/378/story/1393268.html. 
  160. Sahagun, Louis (13 November 2008). "Pollution saps state's economy, study says". Los Angeles Times. http://articles.latimes.com/2008/nov/13/local/me-pollute13. 
  161. Kay, Jane (13 November 2008). "Bad air costing state's economy billions". San Francisco Chronicle. http://www.sfgate.com/health/article/Bad-air-costing-state-s-economy-billions-3185388.php. 
  162. "Human health may be at risk from long-term exposure to air pollution below current air quality standards and guidelines" (in en). British Medical Journal. https://medicalxpress.com/news/2021-09-human-health-long-term-exposure-air.html. 
  163. Strak, Maciej; Weinmayr, Gudrun; Rodopoulou, Sophia; Chen, Jie; Hoogh, Kees de; Andersen, Zorana J.; Atkinson, Richard; Bauwelinck, Mariska et al. (2 September 2021). "Long term exposure to low level air pollution and mortality in eight European cohorts within the ELAPSE project: pooled analysis" (in en). BMJ 374: n1904. doi:10.1136/bmj.n1904. ISSN 1756-1833. PMID 34470785. 
  164. 164.0 164.1 Nansai, Keisuke; Tohno, Susumu; Chatani, Satoru; Kanemoto, Keiichiro; Kagawa, Shigemi; Kondo, Yasushi; Takayanagi, Wataru; Lenzen, Manfred (2 November 2021). "Consumption in the G20 nations causes particulate air pollution resulting in two million premature deaths annually" (in en). Nature Communications 12 (1): 6286. doi:10.1038/s41467-021-26348-y. ISSN 2041-1723. PMID 34728619. Bibcode2021NatCo..12.6286N. 
  165. 165.0 165.1 Vohra, Karn; Vodonos, Alina; Schwartz, Joel; Marais, Eloise A.; Sulprizio, Melissa P.; Mickley, Loretta J. (1 April 2021). "Global mortality from outdoor fine particle pollution generated by fossil fuel combustion: Results from GEOS-Chem" (in en). Environmental Research 195: 110754. doi:10.1016/j.envres.2021.110754. ISSN 0013-9351. PMID 33577774. Bibcode2021ER....195k0754V. https://www.sciencedirect.com/science/article/abs/pii/S0013935121000487. Retrieved 5 March 2021. 
  166. Mackenzie, Jillian; Turrentine, Jeff (June 22, 2021). "Air Pollution: Everything You Need to Know" (in en). https://www.nrdc.org/stories/air-pollution-everything-you-need-know. 
  167. "Air pollution causing 65,000 annual deaths in Middle East, report finds" (in en). 24 July 2020. https://www.thenational.ae/uae/science/air-pollution-causing-65-000-annual-deaths-in-middle-east-report-finds-1.1053843. 
  168. Lucking, A. J.; Lundback, M.; Mills, N. L.; Faratian, D.; Barath, S. L.; Pourazar, J.; Cassee, F. R.; Donaldson, K. et al. (2008). "Diesel exhaust inhalation increases thrombus formation in man". European Heart Journal 29 (24): 3043–51. doi:10.1093/eurheartj/ehn464. PMID 18952612. 
  169. Törnqvist, H. K.; Mills, N. L.; Gonzalez, M.; Miller, M. R.; Robinson, S. D.; Megson, I. L.; MacNee, W.; Donaldson, K. et al. (2007). "Persistent Endothelial Dysfunction in Humans after Diesel Exhaust Inhalation". American Journal of Respiratory and Critical Care Medicine 176 (4): 395–400. doi:10.1164/rccm.200606-872OC. PMID 17446340. 
  170. "Air pollution from G20 consumers caused two million deaths in 2010". New Scientist. https://www.newscientist.com/article/2295873-air-pollution-from-g20-consumers-caused-two-million-deaths-in-2010/. 
  171. Pope, C. A. (15 December 2003). "Cardiovascular Mortality and Long-Term Exposure to Particulate Air Pollution: Epidemiological Evidence of General Pathophysiological Pathways of Disease". Circulation 109 (1): 71–77. doi:10.1161/01.CIR.0000108927.80044.7F. PMID 14676145. 
  172. Green, Matthew (9 February 2021). "Fossil fuel pollution causes one in five premature deaths globally: study" (in en). Reuters. https://www.reuters.com/article/us-health-pollution-fossil-idUSKBN2A90UB. 
  173. Whitacre, Paula (9 February 2021). "Air Pollution Accounts for 1 in 8 Deaths Worldwide, According to New WHO Estimates" (in en). National Institute of Environmental Health Sciences. https://www.niehs.nih.gov/research/programs/geh/geh_newsletter/2014/4/articles/air_pollution_accounts_for_1_in_8_deaths_worldwide_according_to_new_who_estimates.cfm. 
  174. 174.0 174.1 174.2 Chen, H.; Goldberg, M.S.; Villeneuve, P.J. (Oct–Dec 2008). "A systematic review of the relation between long-term exposure to ambient air pollution and chronic diseases.". Reviews on Environmental Health 23 (4): 243–97. doi:10.1515/reveh.2008.23.4.243. PMID 19235364. 
  175. Mateen, F. J.; Brook, R. D. (2011). "Air Pollution as an Emerging Global Risk Factor for Stroke". JAMA 305 (12): 1240–41. doi:10.1001/jama.2011.352. PMID 21427378. 
  176. Miller, K. A.; Siscovick, D. S.; Sheppard, L.; Shepherd, K.; Sullivan, J. H.; Anderson, G. L.; Kaufman, J. D. (2007). "Long-term exposure to air pollution and incidence of cardiovascular events in women.". The New England Journal of Medicine 356 (5): 447–58. doi:10.1056/NEJMoa054409. PMID 17267905. 
  177. Andersen, Z. J.; Kristiansen, L. C.; Andersen, K. K.; Olsen, T. S.; Hvidberg, M.; Jensen, S. S.; Raaschou-Nielsen, O. (2011). "Stroke and Long-Term Exposure to Outdoor Air Pollution From Nitrogen Dioxide: A Cohort Study". Stroke 43 (2): 320–25. doi:10.1161/STROKEAHA.111.629246. PMID 22052517. 
  178. Provost, E.; Madhloum, N.; Int Panis, L.; De Boever, P.; Nawrot, T.S. (May 2015). "Carotid intima-media thickness, a marker of subclinical atherosclerosis, and particulate air pollution exposure: the meta-analytical evidence". PLOS ONE 10 (5): e0127014. doi:10.1371/journal.pone.0127014. PMID 25970426. Bibcode2015PLoSO..1027014P. 
  179. Brook, R.D.; Rajagopalan, S.; Pope, C.A. III; Brook, J.R.; Bhatnagar, A. (2010). "Particulate matter air pollution and cardiovascular disease: An update to the scientific statement from the American Heart Association". Circulation 121 (21): 2331–78. doi:10.1161/cir.0b013e3181dbece1. PMID 20458016. 
  180. Louwies, T.; Int Panis, L.; Kicinski, M.; De Boever, P.; Nawrot, Tim S. (2013). "Retinal Microvascular Responses to Short-Term Changes in Particulate Air Pollution in Healthy Adults". Environmental Health Perspectives 121 (9): 1011–16. doi:10.1289/ehp.1205721. PMID 23777785. 
  181. Gehring, U.; Wijga, A. H.; Brauer, M.; Fischer, P.; de Jongste, J. C.; Kerkhof, M.; Brunekreef, B. (2010). "Traffic-related air pollution and the development of asthma and allergies during the first 8 years of life". American Journal of Respiratory and Critical Care Medicine 181 (6): 596–603. doi:10.1164/rccm.200906-0858OC. PMID 19965811. 
  182. Andersen, Z. J.; Hvidberg, M.; Jensen, S. S.; Ketzel, M.; Loft, S.; Sorensen, M.; Raaschou-Nielsen, O. (2011). "Chronic obstructive pulmonary disease and long-term exposure to traffic-related air pollution: a cohort study. [Research Support, Non-U.S. Gov't].". American Journal of Respiratory and Critical Care Medicine 183 (4): 455–461. doi:10.1164/rccm.201006-0937OC. PMID 20870755. 
  183. Committee of the Environmental and Occupational Health Assembly of the American Thoracic Society (1996). "Health effects of outdoor air pollution". American Journal of Respiratory and Critical Care Medicine 153 (1): 3–50. doi:10.1164/ajrccm.153.1.8542133. PMID 8542133. 
  184. Andersen, Z. J.; Bonnelykke, K.; Hvidberg, M.; Jensen, S. S.; Ketzel, M.; Loft, S.; Raaschou-Nielsen, O. (2011). "Long-term exposure to air pollution and asthma hospitalisations in older adults: a cohort study". Thorax 67 (1): 6–11. doi:10.1136/thoraxjnl-2011-200711. PMID 21890573. 
  185. Zoidis, John D. (1999). "The Impact of Air Pollution on COPD". RT: For Decision Makers in Respiratory Care. http://www.rtmagazine.com/2007/02/the-impact-of-air-pollution-on-copd/. 
  186. "Understanding Air Pollution" (in en). https://resphealth.org/clean-air/understanding-air-pollution/. 
  187. Holland WW, Reid DD. "The urban factor in chronic bronchitis" Lancet 1965;I:445–448.
  188. Gauderman, W. (2007). "Effect of exposure to traffic on lung development from 10 to 18 years of age: a cohort study". The Lancet 369 (9561): 571–77. doi:10.1016/S0140-6736(07)60037-3. PMID 17307103. 
  189. Int Panis, L. (2017). "Short-term air pollution exposure decreases lung function: a repeated measures study in healthy adults". Environmental Health 16 (1): 60. doi:10.1186/s12940-017-0271-z. PMID 28615020. Bibcode2017EnvHe..16...60I. 
  190. Sunyer, J. (2001). "Urban air pollution and Chronic Obstructive Pulmonary disease: a review". European Respiratory Journal 17 (5): 1024–33. doi:10.1183/09031936.01.17510240. PMID 11488305. 
  191. "Ambient air pollution" (in en). https://www.who.int/data/gho/data/themes/topics/indicator-groups/indicator-group-details/GHO/ambient-air-pollution. 
  192. "Education Data, Visualizations & Graphics on Air Quality and PM2.5" (in en). https://www.cleanairresources.com/data. 
  193. Gallagher, James (17 December 2015). "Cancer is not just 'bad luck' but down to environment, study suggests". BBC. https://www.bbc.co.uk/news/health-35111449. 
  194. 194.0 194.1 "Cancer breakthrough is a 'wake-up' call on danger of air pollution" (in en). The Guardian. 2022-09-10. https://www.theguardian.com/science/2022/sep/10/cancer-breakthrough-is-a-wake-up-call-on-danger-of-air-pollution. 
  195. Saber, E.M.; Heydari, G. (May 2012). "Flow patterns and deposition fraction of particles in the range of 0.1–10 μm at trachea and the first third generations under different breathing conditions". Computers in Biology and Medicine 42 (5): 631–38. doi:10.1016/j.compbiomed.2012.03.002. PMID 22445097. 
  196. Raaschou-Nielsen, O.; Andersen, Z. J.; Hvidberg, M.; Jensen, S. S.; Ketzel, M.; Sorensen, M.; Tjonneland, A. (2011). "Lung cancer incidence and long-term exposure to air pollution from traffic. [Research Support, Non-U.S. Gov't."]. Environmental Health Perspectives 119 (6): 860–65. doi:10.1289/ehp.1002353. PMID 21227886. 
  197. Raaschou-Nielsen, O.; Andersen, Z. J.; Hvidberg, M.; Jensen, S. S.; Ketzel, M.; Sorensen, M.; Tjonneland, A. (2011). "Air pollution from traffic and cancer incidence: a Danish cohort study". Environmental Health 10 (1): 67. doi:10.1186/1476-069X-10-67. PMID 21771295. Bibcode2011EnvHe..10...67R. 
  198. Yacong Bo (2021). "Reduced Ambient PM2.5 Was Associated with a Decreased Risk of Chronic Kidney Disease: A Longitudinal Cohort Study". Environmental Science & Technology 55 (10): 6876–6883. doi:10.1021/acs.est.1c00552. PMID 33904723. Bibcode2021EnST...55.6876B. 
  199. Blum, Matthew F.; Surapaneni, Aditya; Stewart, James D.; Liao, Duanping; Yanosky, Jeff D.; Whitsel, Eric A.; Power, Melinda C.; Grams, Morgan E. (2020-03-06). "Particulate Matter and Albuminuria, Glomerular Filtration Rate, and Incident CKD" (in en). Clinical Journal of the American Society of Nephrology 15 (3): 311–319. doi:10.2215/CJN.08350719. ISSN 1555-9041. PMID 32108020. PMC 7057299. https://cjasn.asnjournals.org/content/15/3/311. 
  200. 200.0 200.1 200.2 200.3 200.4 200.5 Conforti, Alessandro; Mascia, Marika; Cioffi, Giuseppina; De Angelis, Cristina; Coppola, Giuseppe; De Rosa, Pasquale; Pivonello, Rosario; Alviggi, Carlo et al. (2018-12-30). "Air pollution and female fertility: a systematic review of literature". Reproductive Biology and Endocrinology 16 (1): 117. doi:10.1186/s12958-018-0433-z. ISSN 1477-7827. PMID 30594197. 
  201. Canipari, Rita; De Santis, Lucia; Cecconi, Sandra (January 2020). "Female Fertility and Environmental Pollution" (in en). International Journal of Environmental Research and Public Health 17 (23): 8802. doi:10.3390/ijerph17238802. ISSN 1660-4601. PMID 33256215. 
  202. da Silva Junior, Francisco Carlos; Felipe, Maria Beatriz Mesquita Cansanção; Castro, Denis Elvis Farias de; Araújo, Sinara Carla da Silva; Sisenando, Herbert Costa Nóbrega; Batistuzzo de Medeiros, Silvia Regina (2021-06-01). "A look beyond the priority: A systematic review of the genotoxic, mutagenic, and carcinogenic endpoints of non-priority PAHs" (in en). Environmental Pollution 278: 116838. doi:10.1016/j.envpol.2021.116838. ISSN 0269-7491. PMID 33714059. https://www.sciencedirect.com/science/article/pii/S0269749121004188. 
  203. Plunk, Elizabeth C.; Richards, Sean M. (January 2020). "Endocrine-Disrupting Air Pollutants and Their Effects on the Hypothalamus-Pituitary-Gonadal Axis" (in en). International Journal of Molecular Sciences 21 (23): 9191. doi:10.3390/ijms21239191. ISSN 1422-0067. PMID 33276521. 
  204. Perono, Genevieve A; Petrik, James J; Thomas, Philippe J; Holloway, Alison C (2022-01-01). "The effects of polycyclic aromatic compounds (PACs) on mammalian ovarian function" (in en). Current Research in Toxicology 3: 100070. doi:10.1016/j.crtox.2022.100070. ISSN 2666-027X. PMID 35492299. 
  205. 205.0 205.1 Jurewicz, Joanna; Dziewirska, Emila; Radwan, Michał; Hanke, Wojciech (2018-12-23). "Air pollution from natural and anthropic sources and male fertility" (in en). Reproductive Biology and Endocrinology 16 (1): 109. doi:10.1186/s12958-018-0430-2. ISSN 1477-7827. PMID 30579357. 
  206. 206.0 206.1 Frutos, Víctor; González-Comadrán, Mireia; Solà, Ivan; Jacquemin, Benedicte; Carreras, Ramón; Checa Vizcaíno, Miguel A. (2015-01-02). "Impact of air pollution on fertility: a systematic review". Gynecological Endocrinology 31 (1): 7–13. doi:10.3109/09513590.2014.958992. ISSN 0951-3590. PMID 25212280. https://doi.org/10.3109/09513590.2014.958992. 
  207. Checa Vizcaíno, Miguel A.; González-Comadran, Mireia; Jacquemin, Benedicte (September 2016). "Outdoor air pollution and human infertility: a systematic review". Fertility and Sterility 106 (4): 897–904.e1. doi:10.1016/j.fertnstert.2016.07.1110. ISSN 0015-0282. PMID 27513553. http://dx.doi.org/10.1016/j.fertnstert.2016.07.1110. 
  208. 208.0 208.1 208.2 Carré, Julie; Gatimel, Nicolas; Moreau, Jessika; Parinaud, Jean; Léandri, Roger (2017-07-28). "Does air pollution play a role in infertility?: a systematic review". Environmental Health 16 (1): 82. doi:10.1186/s12940-017-0291-8. ISSN 1476-069X. PMID 28754128. Bibcode2017EnvHe..16...82C. 
  209. Jurewicz, Joanna; Dziewirska, Emila; Radwan, Michał; Hanke, Wojciech (2018). "Air pollution from natural and anthropic sources and male fertility" (in en). Reproductive Biology and Endocrinology 16 (1): 109. doi:10.1186/s12958-018-0430-2. PMID 30579357. PMC 6304234. https://rdcu.be/cWWgF. Retrieved 2022-10-05. 
  210. Committee on Environmental Health (2004). "Ambient Air Pollution: Health Hazards to Children". Pediatrics 114 (6): 1699–707. doi:10.1542/peds.2004-2166. PMID 15574638. 
  211. "Polluted Cities: The Air Children Breathe". World Health Organization. https://www.who.int/ceh/publications/en/11airpollution.pdf. 
  212. Pieters, N.; Koppen, G.; Van Poppel, M.; De Prins, S.; Cox, B.; Dons, E.; Nelen, V.; Int Panis, L. et al. (March 2015). "Blood Pressure and Same-Day Exposure to Air Pollution at School: Associations with Nano-Sized to Coarse PM in Children". Environmental Health Perspectives 123 (7): 737–42. doi:10.1289/ehp.1408121. PMID 25756964. 
  213. AFP (30 October 2018). "Air pollution kills 600,000 children: WHO". The News International. https://www.thenews.com.pk/print/387232-air-pollution-kills-600-000-children-who. 
  214. Perera, Frederica P.; Tang, Deliang; Wang, Shuang; Vishnevetsky, Julia; Zhang, Bingzhi; Diaz, Diurka; Camann, David; Rauh, Virginia (1 June 2012). "Prenatal Polycyclic Aromatic Hydrocarbon (PAH) Exposure and Child Behavior at Age 6–7 Years". Environmental Health Perspectives 120 (6): 921–926. doi:10.1289/ehp.1104315. PMID 22440811. 
  215. Perera, Frederica P.; Chang, Hsin-wen; Tang, Deliang; Roen, Emily L.; Herbstman, Julie; Margolis, Amy; Huang, Tzu-Jung; Miller, Rachel L. et al. (5 November 2014). "Early-Life Exposure to Polycyclic Aromatic Hydrocarbons and ADHD Behavior Problems" (in en). PLOS ONE 9 (11): e111670. doi:10.1371/journal.pone.0111670. ISSN 1932-6203. PMID 25372862. Bibcode2014PLoSO...9k1670P. 
  216. Becerra, Tracy Ann; Wilhelm, Michelle; Olsen, Jørn; Cockburn, Myles; Ritz, Beate (1 March 2013). "Ambient Air Pollution and Autism in Los Angeles County, California". Environmental Health Perspectives 121 (3): 380–386. doi:10.1289/ehp.1205827. PMID 23249813. 
  217. Perera, Frederica; Herbstman, Julie (1 April 2011). "Prenatal environmental exposures, epigenetics, and disease" (in en). Reproductive Toxicology. Prenatal Programming and Toxicity II (PPTOX II): Role of Environmental Stressors in the Developmental Origins of Disease 31 (3): 363–373. doi:10.1016/j.reprotox.2010.12.055. ISSN 0890-6238. PMID 21256208. 
  218. Papamitsou, T.; Sirak, S.; Kavvadas, D. (January–March 2020). "Air pollution and preterm birth: a recommendation for further study in Greece". Hippokratia 24 (1): 44. PMID 33364740. 
  219. Fleischer, Nancy L.; Merialdi, Mario; van Donkelaar, Aaron; Vadillo-Ortega, Felipe; Martin, Randall V.; Betran, Ana Pilar; Souza, João Paulo (1 April 2014). "Outdoor air pollution, preterm birth, and low birth weight: analysis of the World Health Organization global survey on maternal and perinatal health". Environmental Health Perspectives 122 (4): 425–30. doi:10.1289/ehp.1306837. ISSN 1552-9924. PMID 24508912. 
  220. 220.0 220.1 220.2 Malley, Christopher S.; Kuylenstierna, Johan C. I.; Vallack, Harry W.; Henze, Daven K.; Blencowe, Hannah; Ashmore, Mike R. (1 April 2017). "Preterm birth associated with maternal fine particulate matter exposure: A global, regional and national assessment". Environment International 101: 173–82. doi:10.1016/j.envint.2017.01.023. ISSN 1873-6750. PMID 28196630. http://eprints.whiterose.ac.uk/112553/1/Malley_2017_Environment_International.pdf. 
  221. Bank, European Investment (2022-10-19) (in EN). Finance in Africa - Navigating the financial landscape in turbulent times. European Investment Bank. ISBN 978-92-861-5382-2. https://www.eib.org/en/publications/finance-in-africa-navigating-the-financial-landscape-in-turbulent-times. 
  222. "Silent Suffocation in Africa - Air Pollution is a Growing Menace, Affecting the Poorest Children the Most". https://www.unicef.org/media/55081/file/Silent_suffocation_in_africa_air_pollution_2019.pdf. 
  223. "The cost of air pollution in Africa" (in en). https://www.un.org/africarenewal/documents/cost-air-pollution-africa. 
  224. Wang, X.; Ding, H.; Ryan, L.; Xu, X. (1 May 1997). "Association between air pollution and low birth weight: a community-based study". Environmental Health Perspectives 105 (5): 514–20. doi:10.1289/ehp.97105514. ISSN 0091-6765. PMID 9222137. 
  225. Brauer, Michael; Lencar, Cornel; Tamburic, Lillian; Koehoorn, Mieke; Demers, Paul; Karr, Catherine (1 May 2008). "A Cohort Study of Traffic-Related Air Pollution Impacts on Birth Outcomes". Environmental Health Perspectives 116 (5): 680–6. doi:10.1289/ehp.10952. PMID 18470315. 
  226. Qian, Di (29 June 2017). "Air Pollution and Mortality in the Medicare Population". New England Journal of Medicine 376 (26): 2513–2522. doi:10.1056/NEJMoa1702747. PMID 28657878. 
  227. "2005 BC Lung Association report on the valuation of health impacts from air quality in the Lower Fraser Valley airshed". http://www.bc.lung.ca/pdf/health_and_air_quality_2005.pdf. 
  228. Pathak, Mansi; Kuttippurath, Jayanarayanan (2022). "Air quality trends in rural India: analysis of NO2 pollution using satellite measurements" (in en). Environmental Science: Processes & Impacts 24 (12): 2437–2449. doi:10.1039/D2EM00293K. ISSN 2050-7887. PMID 36413251. https://pubs.rsc.org/en/content/articlelanding/2022/EM/D2EM00293K. 
  229. Woodyatt, Amy (3 June 2020). "Scientists say they have found the cleanest air on Earth". https://www.cnn.com/2020/06/02/world/cleanest-air-intl-scli-scn-climate/index.html. 
  230. Bos, I.; De Boever, P.; Int Panis, L.; Meeusen, R. (2014). "Physical Activity, Air Pollution and the Brain.". Sports Medicine 44 (11): 1505–18. doi:10.1007/s40279-014-0222-6. PMID 25119155. https://www.researchgate.net/publication/264793941. 
  231. Air pollution linked to much greater risk of dementia The Guardian
  232. Julvez, Jordi; López-Vicente, Mónica; Warembourg, Charline; Maitre, Lea; Philippat, Claire; Gützkow, Kristine B.; Guxens, Monica; Evandt, Jorunn et al. (1 September 2021). "Early life multiple exposures and child cognitive function: A multi-centric birth cohort study in six European countries" (in en). Environmental Pollution 284: 117404. doi:10.1016/j.envpol.2021.117404. ISSN 0269-7491. PMID 34077897. 
  233. 233.0 233.1 Costa, Lucio G.; Cole, Toby B.; Dao, Khoi; Chang, Yu-Chi; Coburn, Jacki; Garrick, Jacqueline M. (June 2020). "Effects of air pollution on the nervous system and its possible role in neurodevelopmental and neurodegenerative disorders". Pharmacology & Therapeutics 210: 107523. doi:10.1016/j.pharmthera.2020.107523. ISSN 1879-016X. PMID 32165138. 
  234. Volk, Heather E.; Perera, Frederica; Braun, Joseph M.; Kingsley, Samantha L.; Gray, Kimberly; Buckley, Jessie; Clougherty, Jane E.; Croen, Lisa A. et al. (1 May 2021). "Prenatal air pollution exposure and neurodevelopment: A review and blueprint for a harmonized approach within ECHO" (in en). Environmental Research 196: 110320. doi:10.1016/j.envres.2020.110320. ISSN 0013-9351. PMID 33098817. Bibcode2021ER....196k0320V. 
  235. Shang, Li; Yang, Liren; Yang, Wenfang; Huang, Liyan; Qi, Cuifang; Yang, Zixuan; Fu, Zhuxuan; Chung, Mei Chun (1 July 2020). "Effects of prenatal exposure to NO2 on children's neurodevelopment: a systematic review and meta-analysis" (in en). Environmental Science and Pollution Research 27 (20): 24786–24798. doi:10.1007/s11356-020-08832-y. ISSN 1614-7499. PMID 32356052. 
  236. Symons, Angela (2022-12-15). "Suicide rates rise as air quality worsens, study finds" (in en). https://www.euronews.com/green/2022/12/15/suicide-may-be-more-common-in-areas-worst-hit-by-air-pollution-new-study-reveals. 
  237. Allen, Joshua L.; Liu, Xiufang; Pelkowski, Sean; Palmer, Brian; Conrad, Katherine; Oberdörster, Günter; Weston, Douglas; Mayer-Pröschel, Margot et al. (5 June 2014). "Early Postnatal Exposure to Ultrafine Particulate Matter Air Pollution: Persistent Ventriculomegaly, Neurochemical Disruption, and Glial Activation Preferentially in Male Mice". Environmental Health Perspectives 122 (9): 939–945. doi:10.1289/ehp.1307984. ISSN 0091-6765. PMID 24901756. 
  238. McEnaney, Michael (7 June 2014). "Air pollution link discovered to autism, schizophrenia risks". http://www.techtimes.com/articles/8147/20140607/air-pollution-link-discovered-autism-schizophrenia-risks.htm. 
  239. "New Evidence Links Air Pollution to Autism, Schizophrenia". University of Rochester Medical Center. 6 June 2014. http://www.urmc.rochester.edu/news/story/index.cfm?id=4100. 
  240. "New Study Demonstrates Indoor Building Environment Has Significant, Positive Impact on Cognitive Function". The New York Times. 26 October 2015. http://markets.on.nytimes.com/research/stocks/news/press_release.asp. 
  241. Allen, Joseph G.; MacNaughton, Piers; Satish, Usha; Santanam, Suresh; Vallarino, Jose; Spengler, John D. (2015). "Associations of Cognitive Function Scores with Carbon Dioxide, Ventilation, and Volatile Organic Compound Exposures in Office Workers: A Controlled Exposure Study of Green and Conventional Office Environments". Environmental Health Perspectives 124 (6): 805–12. doi:10.1289/ehp.1510037. PMID 26502459. 
  242. Cedeño Laurent, Jose Guillermo; MacNaughton, Piers; Jones, Emily; Young, Anna S; Bliss, Maya; Flanigan, Skye; Vallarino, Jose; Chen, Ling Jyh et al. (1 September 2021). "Associations between acute exposures to PM2.5 and carbon dioxide indoors and cognitive function in office workers: a multicountry longitudinal prospective observational study" (in en). Environmental Research Letters 16 (9): 094047. doi:10.1088/1748-9326/ac1bd8. ISSN 1748-9326. PMID 35330988. Bibcode2021ERL....16i4047C. 
  243. Hong, Chaopeng; Mueller, Nathaniel D.; Burney, Jennifer A. et al. (2020). "Impacts of ozone and climate change on yields of perennial crops in California" (in en). Nature Food 1 (3): 166–172. doi:10.1038/s43016-020-0043-8. https://www.nature.com/articles/s43016-020-0043-8. 
  244. Li, Houjian; Tang, Mengqian; Cao, Andi; Guo, Lili (2022). "Assessing the relationship between air pollution, agricultural insurance, and agricultural green total factor productivity: evidence from China" (in en). Environmental Science and Pollution Research 29 (52): 78381–78395. doi:10.1007/s11356-022-21287-7. ISSN 0944-1344. PMID 35689771. Bibcode2022ESPR...2978381L. https://link.springer.com/10.1007/s11356-022-21287-7. 
  245. Kashyap, Rahul; Kuttippurath, J.; Patel, V. K. (2023). "Improved air quality leads to enhanced vegetation growth during the COVID–19 lockdown in India" (in en). Applied Geography 151: 102869. doi:10.1016/j.apgeog.2022.102869. ISSN 0143-6228. PMID 36619606. Bibcode2023AppGe.15102869K. 
  246. Kuttippurath, J.; Singh, A.; Dash, S. P. et al. (2020). "Record high levels of atmospheric ammonia over India: Spatial and temporal analyses" (in en). Science of the Total Environment 740: 139986. doi:10.1016/j.scitotenv.2020.139986. ISSN 0048-9697. PMID 32927535. Bibcode2020ScTEn.740m9986K. https://www.sciencedirect.com/science/article/pii/S0048969720335063. 
  247. UN Environment (11 October 2018). "Air pollution linked to "huge" reduction in intelligence". http://www.unenvironment.org/news-and-stories/story/air-pollution-linked-huge-reduction-intelligence. 
  248. Lavy, Victor; Rachkovski, Genia; Yoresh, Omry (2022). Heads Up: Does Air Pollution Cause Workplace Accidents? (Report). Cambridge, MA: National Bureau of Economic Research. doi:10.3386/w30715. https://www.nber.org/papers/w30715. 
  249. Smith, Adam (12 February 2021). "Pollution on other planets could help us find aliens, Nasa says" (in en). The Independent. https://www.independent.co.uk/life-style/gadgets-and-tech/alien-pollution-planets-nasa-b1801543.html. 
  250. "Can Alien Smog Lead Us to Extraterrestrial Civilizations?" (in en-us). Wired. https://www.wired.com/story/can-alien-smog-lead-us-to-extraterrestrial-civilizations/. 
  251. Kopparapu, Ravi; Arney, Giada; Haqq-Misra, Jacob; Lustig-Yaeger, Jacob; Villanueva, Geronimo (22 February 2021). "Nitrogen Dioxide Pollution as a Signature of Extraterrestrial Technology" (in en). The Astrophysical Journal 908 (2): 164. doi:10.3847/1538-4357/abd7f7. ISSN 1538-4357. Bibcode2021ApJ...908..164K. 
  252. Chakrabarti, Simi. "20th anniversary of world's worst industrial disaster". Australian Broadcasting Corporation. http://www.abc.net.au/worldtoday/content/2004/s1257352.htm. 
  253. Bell, Michelle L.; Davis, Devra L.; Fletcher, Tony (January 2004). "A Retrospective Assessment of Mortality from the London Smog Episode of 1952: The Role of Influenza and Pollution". Environ Health Perspect 112 (1): 6–8. doi:10.1289/ehp.6539. PMID 14698923. 
  254. "The Sverdlovsk anthrax outbreak of 1979". Science 266 (5188): 1202–08. November 1994. doi:10.1126/science.7973702. PMID 7973702. Bibcode1994Sci...266.1202M. http://www.anthrax.osd.mil/documents/library/Sverdlovsk.pdf. 
  255. Davis, Devra (2002). When Smoke Ran Like Water: Tales of Environmental Deception and the Battle Against Pollution. Basic Books. ISBN 978-0-465-01521-4. https://archive.org/details/whensmokeranlike00davi. 
  256. Landrigan, P (25 November 2016). "Air pollution and health". Lancet 2 (1): E4–E5. doi:10.1016/S2468-2667(16)30023-8. PMID 29249479. 
  257. Camahan, James V.; Thurston, Deborah L. (1998). "Trade-off Modeling for Product and Manufacturing Process Design for the Environment" (in en). Journal of Industrial Ecology 2 (1): 79–92. doi:10.1162/jiec.1998.2.1.79. ISSN 1530-9290. Bibcode1998JInEc...2...79C. 
  258. Jacobson, Mark Z.; von Krauland, Anna-Katharina; Coughlin, Stephen J.; Palmer, Frances C.; Smith, Miles M. (1 January 2022). "Zero air pollution and zero carbon from all energy at low cost and without blackouts in variable weather throughout the U.S. with 100% wind-water-solar and storage" (in en). Renewable Energy 184: 430–442. doi:10.1016/j.renene.2021.11.067. ISSN 0960-1481. https://www.sciencedirect.com/science/article/abs/pii/S0960148121016499. 
  259. Gielen, Dolf; Boshell, Francisco; Saygin, Deger; Bazilian, Morgan D.; Wagner, Nicholas; Gorini, Ricardo (1 April 2019). "The role of renewable energy in the global energy transformation" (in en). Energy Strategy Reviews 24: 38–50. doi:10.1016/j.esr.2019.01.006. ISSN 2211-467X. 
  260. Burns, J; Boogaard, H; Polus, S; Pfadenhauer, LM; Rohwer, AC; van-Erp, AM; Turley, R; Rehfeuss, E (20 May 2019). "Interventions to Reduce Ambient Particulate Matter Air Pollution and Their Effect on Health". Cochrane Database of Systematic Reviews 2019 (5): CD010919. doi:10.1002/14651858.CD010919.pub2. PMID 31106396. 
  261. Connolly, Kate (30 August 2022). "Germany's €9 train tickets scheme 'saved 1.8m tons of CO
    2
    emissions'"
    . The Guardian. https://www.theguardian.com/world/2022/aug/30/germanys-9-train-tickets-scheme-saved-18m-tons-of-co2-emissions.
     
  262. "The Importance of Development Plans/Land Use Policy for Development Control". http://www.oas.org/pgdm/document/bitc/papers/dthomas.htm. 
  263. Kuttippurath, J.; Patel, V. K.; Pathak, M.; Singh, A. (2022). "Improvements in SO2 pollution in India: role of technology and environmental regulations" (in en). Environmental Science and Pollution Research 29 (52): 78637–78649. doi:10.1007/s11356-022-21319-2. ISSN 1614-7499. PMID 35696063. Bibcode2022ESPR...2978637K. 
  264. Palmer, Jason (12 November 2011). "'Smog-Eating' Material Breaking into the Big Time". BBC News. https://www.bbc.co.uk/news/science-environment-15694973. 
  265. "Nanotechnology to gobble up pollution". BBC News. 15 May 2014. https://www.bbc.com/news/science-environment-27425217. 
  266. 266.0 266.1 Jacobson, Mark Z. (2015). "100% clean and renewable wind, water, and sunlight (WWS) all-sector energy road maps for the 50 United States". Energy and Environmental Science 8 (7): 2093–2117. doi:10.1039/C5EE01283J. 
  267. Landrigan, Philip J. (1 January 2017). "Air pollution and health" (in English). The Lancet Public Health 2 (1): e4–e5. doi:10.1016/S2468-2667(16)30023-8. ISSN 2468-2667. PMID 29249479. 
  268. Lyons, T. J.; Kenworthy, J. R.; Newman, P. W. G. (1 January 1990). "Urban structure and air pollution" (in en). Atmospheric Environment. Part B. Urban Atmosphere 24 (1): 43–48. doi:10.1016/0957-1272(90)90008-I. ISSN 0957-1272. Bibcode1990AtmEB..24...43L. 
  269. McVeigh, Karen (28 September 2021). "'False choice': is deep-sea mining required for an electric vehicle revolution?" (in en). The Guardian. https://www.theguardian.com/environment/2021/sep/28/false-choice-is-deep-sea-mining-required-for-an-electric-vehicle-revolution. 
  270. Opray, Max (24 August 2017). "Nickel mining: the hidden environmental cost of electric cars" (in en). The Guardian. https://www.theguardian.com/sustainable-business/2017/aug/24/nickel-mining-hidden-environmental-cost-electric-cars-batteries. 
  271. "Los Angeles Airport Pollutes City Air For Miles Downwind". Chemical and Engineering news. 30 May 2014. https://cen.acs.org/articles/92/web/2014/05/Los-Angeles-Airport-Pollutes-City.html. 
  272. "NASA Confirms Biofuels Reduce Jet Emissions". 23 March 2017. http://www.flyingmag.com/nasa-confirms-biofuels-reduce-jet-emissions. 
  273. "Interseasonal Heat Transfer™ – Seasonal Heat Storage – GSHC – Renewable Heat & Renewable Cooling from ThermalBanks – Efficient Renewable Energy – Hybrid Renewable Energy Systems". http://www.icax.co.uk/interseasonal_heat_transfer.html. 
  274. Ahuja, Dilip; Tatsutani, Marika (2009-04-07). "Sustainable energy for developing countries" (in fr). S.A.P.I.EN.S 2 (1). ISSN 1993-3800. https://journals.openedition.org/sapiens/823. 
  275. Oyedepo, Sunday Olayinka (2012-07-23). "Energy and sustainable development in Nigeria: the way forward". Energy, Sustainability and Society 2 (1): 15. doi:10.1186/2192-0567-2-15. ISSN 2192-0567. 
  276. "Road Rubber". http://sciencenetlinks.com/science-news/science-updates/road-rubber/. 
  277. Simeonova, Emilia (March 2018). Congestion Pricing, Air Pollution and Children's Health. Working Paper Series. doi:10.3386/w24410. http://www.nber.org/papers/w24410. 
  278. Academy, Samphina (2022-04-16). "Impact Of Air Pollution On The Environment" (in en-US). https://samphina.com.ng/impact-air-pollution-environment/. 
  279. "Subway air pollution damages passenger health". https://www.chemistryworld.com/news/subway-air-pollution-damages-passenger-health/3007012.article. 
  280. European Commission (11 May 2011). "European Commission - Environment - Air - Air quality". http://ec.europa.eu/environment/air/quality/legislation/directive.htm. 
  281. Canada, Environment and Climate Change (2007-09-10). "About the Air Quality Health Index". https://www.canada.ca/en/environment-climate-change/services/air-quality-health-index/about.html. 
  282. "Environment Canada – Air Quality". 10 September 2007. http://www.ec.gc.ca/cas-aqhi/default.asp?lang=En&n=065BE995-1. 
  283. "Environment Canada – AQHI categories and explanations". 16 April 2008. http://www.ec.gc.ca/cas-aqhi/default.asp?lang=En&n=79A8041B-1. 
  284. "German TA-Luft is guaranteed by us" (in en-US). https://www.centrotherm-cs.de/en/innovation/news-journal/detail/?cHash=2f8c3c73736a8bfee683c94544e0d805&tx_news_pi1%5Baction%5D=detail&tx_news_pi1%5Bcontroller%5D=News&tx_news_pi1%5Bnews%5D=9. 
  285. 285.0 285.1 Europa (1996). "Summaries of EU legislation – Management and quality of ambient air". http://europa.eu/legislation_summaries/other/l28031a_en.htm. 
  286. European Court of Justice, CURIA (2008). "PRESS RELEASE No 58/08 Judgment of the Court of Justice in Case C-237/07". http://curia.europa.eu/en/actu/communiques/cp08/aff/cp080058en.pdf. 
  287. Overview of relevant case law and critical state of air pollution protection in the EU: Winfried Huck, Jennifer Maaß, Saparya Sood, Tahar Benmaghnia, Alexander Schulte, Sarah Heß and Marc-Anthony Walter, The Right to Breathe Clean Air and Access to Justice - Legal State of Play in International, European and National Law (2021) in 8(22) International Institutions: Transnational Networks eJournal, available at: http://dx.doi.org/10.2139/ssrn.3808572
  288. European Commission. "Air quality: Commission sends final warning to UK over levels of fine particle pollution". http://ec.europa.eu/unitedkingdom/press/press_releases/2010/pr1055_en.htm. 
  289. House of Commons Environmental Audit Committee (2010). "Environmental Audit Committee – Fifth Report Air Quality". https://publications.parliament.uk/pa/cm200910/cmselect/cmenvaud/229/22902.htm. 
  290. 290.0 290.1 Mulholland, Hélène (11 March 2011). "Britain fends off threat of £300m fine over London air pollution". The Guardian. https://www.theguardian.com/environment/2011/mar/11/britain-300m-fine-london-air-pollution. 
  291. London Assembly Environment Committee (2009). "Every Breath You Take". https://www.london.gov.uk/sites/default/files/FINAL%20AIR%20QUALITY%20REPORT.pdf. 
  292. BBC (6 December 2010). "Threat to sue over London congestion charge scrapping". BBC News. https://www.bbc.co.uk/news/uk-england-london-11928005. 
  293. Risse-Kappen, T. (1995). Bringing transnational relations back in: non-state actors, domestic structures, and international institutions. Cambridge: Cambridge University Press. pp. 3–34. 
  294. 294.0 294.1 Pattberg, P.; Stripple, J. (2008). "Beyond the public and private divide: remapping transnational climate governance in the 21st century". International Environmental Agreements: Politics, Law and Economics 8 (4): 367–388. doi:10.1007/s10784-008-9085-3. Bibcode2008IEAPL...8..367P. 
  295. Roman, M. (2010). "Governing from the middle: the C40 Cities Leadership Group". Corporate Governance 10 (1): 73–84. doi:10.1108/14720701011021120. 
  296. "Air pollution hot spot". http://www.greenfacts.org/glossary/abc/air-pollution-hot-spot.htm. 
  297. Pettit, David (14 December 2014). "Global Toll of Air Pollution: Over 3 Million Deaths Each Year". Switchboard NRDC. http://switchboard.nrdc.org/blogs/dpettit/global_toll_of_air_pollution_o.html. 
  298. "Watch air pollution flow across the planet in real time". Science Magazine News. 28 November 2016. https://www.science.org/content/article/watch-air-pollution-flow-across-planet-real-time. 
  299. 299.0 299.1 Drury, Richard; Belliveau, Michael; Kuhn, J. Scott; Shipra, Bansal (Spring 1999). "Pollution Trading and Environmental Justice: Los Angeles' Failed Experiment in Air Pollution Policy". Duke Environmental Law & Policy Forum 9 (231). 
  300. 300.0 300.1 Morello-Frosch, Rachel; Zuk, Miriam; Jerrett, Michael; Shamasunder, Bhavna; Kyle, Amy D. (2011). "Understanding the Cumulative Impacts of Inequalities in Environmental Health: Implications for Policy". Health Affairs 30 (5): 879–87. doi:10.1377/hlthaff.2011.0153. PMID 21555471. 
  301. Mohai, P.; Lantz, P.M.; Morenoff, J.; House, J.S.; Mero, R.P. (2009). "Racial and Socioeocnomic Disparities in Residential Proximity". American Journal of Public Health 99 (3): S649–56. doi:10.2105/ajph.2007.131383. PMID 19890171. 
  302. Lerner, Steve (2010). "Sacrifice Zones: The Front Lines of Toxic Chemical Exposure in the United States". Port Arthur, Texas: Public Housing Residents Breathe Contaminated Air from Nearby Refineries and Chemical Plants (MIT Press). 
  303. Vohra, Karn; Marais, Eloise A.; Bloss, William J.; Schwartz, Joel; Mickley, Loretta J.; Van Damme, Martin; Clarisse, Lieven; Coheur, Pierre-F. (2022-04-08). "Rapid rise in premature mortality due to anthropogenic air pollution in fast-growing tropical cities from 2005 to 2018" (in en). Science Advances 8 (14): eabm4435. doi:10.1126/sciadv.abm4435. ISSN 2375-2548. PMID 35394832. Bibcode2022SciA....8M4435V. 
  304. Michelozzi, P.; Forastiere, F.; Fusco, D.; Perucci, C. A.; Ostro, B.; Ancona, C.; Pallotti, G. (1998). "Air Pollution and Daily Mortality in Rome, Italy". Occupational and Environmental Medicine 55 (9): 605–10. doi:10.1136/oem.55.9.605. PMID 9861182. 
  305. The Daily Telegraph 8 January 2014 'Air pollution killing up to 500,000 Chinese each year, admits former health minister'.
  306. "World's Most Polluted Cities in 2020 - PM2.5 Ranking | AirVisual" (in en-us). https://www.iqair.com/us/world-most-polluted-cities. 
  307. "World Air Quality Index (AQI) Ranking | IQAir" (in en). https://www.iqair.com/world-air-quality-ranking. 
  308. Darame, Mariama (29 November 2019). "En Afrique de l'Ouest, une pollution mortelle mais d'ampleur inconnue" (in fr). https://www.lemonde.fr/afrique/article/2019/11/29/en-afrique-de-l-ouest-une-pollution-mortelle-mais-d-ampleur-inconnue_6021103_3212.html. 
  309. Organisation for Economic Co-operation and Development (1 March 2012). "Environmental Ooutlook to 2050 - OECD". https://www.oecd.org/environment/indicators-modelling-outlooks/49928853.pdf. 

Further reading

  • Brimblecombe, Peter (1987). The Big Smoke: A History of Air Pollution in London Since Medieval Times. Routledge. ISBN 9781136703294. 
  • Brimblecombe, Peter (1995). "1: History of air pollution". in Singh, H.B.. Composition, chemistry, and climate of the atmosphere. New York: John Wiley & Sons. pp. 1–18. ISBN 9780471285144. OCLC 43084000. https://www.worldcat.org/oclc/43084000. 
  • Brimblecombe, Peter; Makra, László (2005). "Selections from the history of environmental pollution, with special attention to air pollution. Part 2*: From medieval times to the 19th century". International Journal of Environment and Pollution 23 (4): 351–67. doi:10.1504/ijep.2005.007599. 
  • Cherni, Judith A. Economic Growth versus the Environment: The Politics of Wealth, Health and Air Pollution (2002) online
  • Corton, Christine L. London Fog: The Biography (2015)
  • Currie, Donya. "WHO: Air Pollution a Continuing Health Threat in World's Cities", The Nation's Health (February 2012) 42#1 online
  • Dewey, Scott Hamilton. Don't Breathe the Air: Air Pollution and US Environmental Politics, 1945–1970 (Texas A & M University Press, 2000)
  • Gonzalez, George A. The politics of air pollution: Urban growth, ecological modernization, and symbolic inclusion (SUNY Press, 2012)
  • Grinder, Robert Dale (1978). "From Insurgency to Efficiency: The Smoke Abatement Campaign in Pittsburgh before World War I.". Western Pennsylvania Historical Magazine 61 (3): 187–202. 
  • Grinder, Robert Dale. "The Battle for Clean Air: The Smoke Problem in Post-Civil War America" in Martin V. Melosi, ed., Pollution & Reform in American Cities, 1870–1930 (1980), pp. 83–103.
  • Kumar, Prashant; Pirjola, Liisa; Ketzel, Matthias; Harrison, Roy M. (2013). "Nanoparticle emissions from 11 non-vehicle exhaust sources – A review". Atmospheric Environment (Elsevier BV) 67: 252–277. doi:10.1016/j.atmosenv.2012.11.011. ISSN 1352-2310. Bibcode2013AtmEn..67..252K. https://openresearch.surrey.ac.uk/view/pdfCoverPage?instCode=44SUR_INST&filePid=13140580700002346&download=true. 
  • Lundqvist, Lennart J. (1980). The Hare and the Tortoise: Clean Air Policy in the US and Sweden. Ann Arbor, MI: University of Michigan Press. ISBN 9780472093106. 
  • Mingle, Jonathan, "Our Lethal Air" [review of Gary Fuller, The Invisible Killer...; Beth Gardiner, Choked...; Tim Smedley, Clearing the Air...; U.S. Environmental Protection Agency, Integrated Science Assessment for Particulate Matter (External Review Draft, 2018); and Chartered Clean Air Scientific Advisory Committee, Letter to EPA Administrator on the EPA's Integrated Science Assessment for Particulate Matter, 11 April 2019], The New York Review of Books, vol. LXVI, no. 14 (26 September 2019), pp. 64–66, 68. "Today, 91 percent of people worldwide live in areas where air pollution levels exceed the World Health Organization's recommended limits. ... [T]here is no safe level of exposure to fine particulate matter. ... Most of these fine particles are a by-product of ... burning ... coal, gasoline, diesel, wood, trash ... These particles can get past the defenses of our upper airways to penetrate deep into our lungs and reach the alveoli ... From there, they cross into the bloodstream and spread throughout the body. They can travel through the nose, up the olfactory nerve, and lodge ... in the brain. They can form deposits on the lining of arteries, constricting blood vessels and raising the likelihood of ... strokes and heart attacks. [T]hey exacerbate respiratory illnesses like asthma and chronic obstructive pulmonary disease ... There's ... evidence linking air pollution exposure to an increased risk of Alzheimer's and other forms of dementia." (p. 64.)
  • Mosley, Stephen. The chimney of the world: a history of smoke pollution in Victorian and Edwardian Manchester. Routledge, 2013.
  • Schreurs, Miranda A. Environmental Politics in Japan, Germany, and the United States (Cambridge University Press, 2002) online
  • Thorsheim, Peter. Inventing Pollution: Coal, Smoke, and Culture in Britain since 1800 (2009)

External links