Air pollution

Human sources

Most of the world's air pollution is from burning fossil fuels for industry, construction, transportation, and heating, although humans make air pollution in many other ways.^[19] For instance, nuclear weapons, toxic gases, germ warfare, and rocketry can cause air pollution.^[20]

Natural sources

Dust from desert can cause poor air quality far from its source. For instance, dust from the Gobi Desert in China and Mongolia can reach Hawaii, and dust from the Sahara reaches the Mediterennean.^[55] Wildfires release smoke and carbon monoxide. During periods of active wildfires, its smoke can make up almost 75% of all air pollution by concentration.^[56]

Radon is a radioactive gas that can build up in buildings from the soil. It can cause lung cancer, especially in smokers. Levels are generally low, but can be elevated in buildings with "leaky" foundations or areas with soils rich in uranium.^[57]

Vegetation, in some regions, emits environmentally significant amounts of volatile organic compounds (VOCs) on warmer days. These VOCs react with human pollution sources – specifically, NO_x, SO₂, and organic carbon – to produce a seasonal haze of secondary pollutants.^[58] 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.^[59]

Volcanic eruptions produce mostly steam (about 79 percent), but also carbon dioxide (12 per cent), sulfur dioxide (6.5 percent), and small amounts of other pollutants, such as chlorine and ash particulates.^[60]

Ammonia

Ammonia (NH₃) is emitted mainly by agricultural waste. 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. Although in wide use, ammonia is both caustic and hazardous.^[64] In the atmosphere, ammonia reacts with oxides of nitrogen and sulfur to form secondary particles.^[65]

Carbon dioxide

Carbon dioxide (CO₂) is mainly emitted by the burning of fossil fuels.^[66] It is potentially lethal at very high concentrations (typically 100 times "normal" atmospheric levels).^[67][68] Although the World Health Organization recognizes CO₂ as a climate pollutant, it does not include the gas in its Air Quality Guidelines or set recommended targets for it.^[69] Workplace exposure limits exist in places like UK (5,000 ppm for long-term exposure and 15,000 ppm for short-term exposure).^[68] Natural disasters like the limnic eruption at Lake Nyos can result in a large sudden release as well.^[70]

CO₂ is sometimes called an air pollutant, because it is the main greenhouse gas responsible for climate change.^[71][72] 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 CO₂ emissions. The Inflation Reduction Act of 2022 amended the Clean Air Act to define CO₂ from fossil fuel burning explicitly as an air pollutant.^[73]

Carbon monoxide

Carbon monoxide (CO) is a colorless, odorless, toxic gas.^[74] It is a product of combustion of fuel such as natural gas, coal or wood. In the past, emissions from vehicles were the main source of CO, but modern vehicles do not emit much CO. Now, wildfires and bonfires are the main source of outdoors CO.^[75] Indoors, CO is a larger problem and mainly comes from cooking and heating.^[76]

Nitrogen oxides

Nitrogen oxides (NO_x), particularly nitrous oxide (NO), are mostly created by the burning of fossil fuels, and in lesser amounts by lightning. Nitrogen dioxide (NO₂) is formed from NO in a reaction with other atmospheric gases.^[77][78] NO and NO₂ can form acid rain, can form into a haze, and can cause nutrient pollution in water.^[79] NO₂ is a reddish-brown toxic gas with a strong odor, whereas NO is odorless and does not have a color.^[80]

Particulate matter

Particulate matter (PM), also known as particle pollution, is a mix of microscopic solid particles or droplets suspended in a gas.^[81] 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 cars, power plants, and industrial processes.^{[citation needed]} Increased levels of fine particles in the air are linked to health hazards such as heart disease,^[82] altered lung function and lung cancer;^[83] a definitive link between fine particulate pollution and higher death rates in urban areas was established by the Harvard Six Cities study, published in 1993.^[84]

Efforts to reduce particulate matter in the air may result in better health.^[85]

Sulfur dioxide

Sulfur dioxide (SO₂) is produced by volcanoes and in various industrial processes. Coal and petroleum often contain sulfur compounds, and their combustion generates sulfur dioxide. High concentrations of SO₂ in the air upon emissions generally also lead to the formation of other sulfur oxides (SOx). SOx can react with other compounds in the atmosphere to form small particles and contribute to particulate matter (PM) pollution [...] At high concentrations, gaseous SOx can harm plants by damaging foliage and decreasing growth. SO₂ and other sulfur oxides can contribute to acid rain.^[86] Further oxidation of SO₂, usually in the presence of a catalyst such as NO₂, forms H₂SO₄, and thus acid rain is formed.

Ground-level ozone

Ground-level ozone (O₃): Ozone is created when NOx and VOCs mix.^[87] 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).^[88] O₃ is largely produced by chemical reactions involving NO_x gases (nitrogen oxides, especially from combustion) and volatile organic compounds in the presence of sunlight. Due to the influence of temperature and sunlight on this reaction, high ozone levels are most common on hot summer afternoons.^[89]

Volatile organic compounds

Volatile organic compounds (VOC) are both indoor and outdoor air pollutants.^[90] VOCs are a large group of compounds which can cause photochemical smog and aerosols impacting climate. The group includes methane, CO, acetone and toluene. Some can cause cancer, such as butadiene and benzene.^[91] Methane is an extremely efficient greenhouse gas which contributes to 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.^{[citation needed]}

Other pollutants

• 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.^[92] 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.^[93]
• Persistent organic pollutants, which can attach to particulates. Persistent organic pollutants (POPs) are organic compounds that are resistant to environmental degradation due to chemical, biological, or photolytic processes. 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.^[94] The Stockholm Convention on Persistent Organic Pollutants identified pesticides and other persistent organic pollutants of concern. These include dioxins and furans which are unintentionally created by combustion of organics, like open burning of plastics, and are endocrine disruptors and mutagens.
• Persistent free radicals connected to airborne fine particles are linked to cardiopulmonary disease.^[95][96]
• Polycyclic aromatic hydrocarbons (PAHs): a group of aromatic compounds formed from the incomplete combustion of organic compounds including coal and oil and tobacco.^[97] Wood burning is another significant source of PAHs.^[98]
• Radioactive pollutants: Produced by nuclear explosions, nuclear events, war explosives, and natural processes such as the radioactive decay of radon.
• Toxic metals, such as lead and mercury, especially their compounds.
• Peroxyacetyl nitrate (C₂H₃NO₅): formed from NO_x and VOCs, like ozone.
• Photochemical smog: particles are formed from gaseous primary contaminants and chemicals.^[99] 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.^[100] 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.
• Microplastics from construction,^[101] cosmetics, clothing, and many other sources.^[102]

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).^[103][104]

• 
  Before flue-gas desulfurization was installed, the emissions from this power plant in New Mexico contained excessive amounts of sulfur dioxide.
• 
  Thermal oxidisers are air pollution abatement options for hazardous air pollutants (HAPs), volatile organic compounds (VOCs), and odorous emissions.
• This video provides an overview of a NASA study on the human fingerprint on global air quality.

Mortality

Estimates of deaths due to air pollution vary.^[119] The 2024 Global Burden of Disease Study estimates that air pollution contributed to 8.1 million deaths in 2021, which is more than 1 in 8 deaths. Outdoor particulate pollution (PM2.5) was the largest cause of death (4.7 million), followed by indoor air pollution (3.1 million) and ozone (0.5 million).^[5]

The WHO estimates that 6.7 million people die from air pollution each year, 4.2 million due to outdoor air pollution.^[120] Roughly 68% of outdoor air pollution-related premature deaths were due to ischaemic heart disease and stroke, 14% due to COPD and 14% due to lung infections (lower respiratory tract infections).^[120]

A study published in 2019 estimated that, for 2015, the number was around 8.8 million, with 5.5 million of these premature deaths due to air pollution from human sources.^[121][122] The global mean loss of life expectancy from air pollution in 2015 was 2.9 years, substantially more than, for example, 0.3 years from all forms of direct violence.^[123]

By region

India and China have the higher number of deaths from air pollution. In India, it contributed to 2.1 million deaths in 2021, whereas China saw 2.4 million deaths.^[124] In some countries, more than 20% of deaths were attributed to air pollution, for instance in Nepal, Bangladesh, Laos and North Korea. Air pollution deaths are high in middle-income countries due to industry and in low-income countries due to the use of solid fuels for cooking.^[125]

Annual premature European deaths from air pollution are estimated at 416,000^[126] to 800,000.^[122] The UK saw some 17,000 deaths in 2021 due to air pollution. Nigeria, Indonesia and Pakistan each saw over 200,000 deaths resulting from air pollution.^[127]

Eliminating energy-related emissions in the United States would prevent 46,900–59,400 premature deaths each year and provide $537–$678 billion in benefits from avoided PM_2.5-related illness and death.^[128] A 2023 study on sulfur dioxide emissions by coal power plants (coal PM_2.5) concluded that "exposure to coal PM_2.5 was associated with 2.1 times greater mortality risk than exposure to PM_2.5 from all sources."^[129] From 1999 to 2020, a total of 460,000 deaths in the US were attributed to coal PM_2.5.^[129]

By source

Further information: § Sources

Deaths caused by accidents and air pollution from fossil fuel use in power plants exceed those caused by production of renewable energy.^[130]

The largest cause of air pollution is fossil fuel combustion^[131] – mostly the production and use of cars, electricity production, and heating.^[132] There are estimated 4.5 million annual premature deaths worldwide due to pollutants released by high-emission power stations and vehicle exhausts.^[133]

A study concluded that PM_2.5 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.^[134][135]

The World Health Organization (WHO) estimates that cooking-related pollution causes 3.8 million annual deaths.^[136] The Global Burden of Disease study estimated the number of deaths in 2021 at 3.1 million.^[137]

Cardiovascular disease

There is strong evidence that air pollution increases the risk of cardiovascular disease, including stroke, high blood pressure, and ischemic heart disease.^[138] According to the Global Burden of Disease Study, air pollution is responsible for 27% of deaths from strokes worldwide and 28% of ischemic heart disease.^[139] The risks are highest in regions with higher air pollution (i.e. Asia), for elderly and for people who are overweight.^[138]

Air pollution is a leading risk factor for stroke, particularly in developing countries where pollutant levels are highest.^[139] A systematic analysis of 17 different risk factors in 188 countries found air pollution is associated with nearly one in three strokes (29%) worldwide (34% of strokes in developing countries versus 10% in developed countries).^[140][141] The mechanisms linking air pollution to increased cardiovascular mortality are not fully understood, but likely systemic inflammation and oxidative stress.^[142]

Lung disease

Air pollution has been associated with increased hospitalization and mortality and COPD (chronic obstructive pulmonary disease).^[143] COPD is a common disease which causes breathing difficulties and is the fourth-largest cause of death globally.^[144] Almost half of COPD deaths are due to air pollution.^[139] Fine particles (PM_2.5) or NO₂ were associated with increased risk of developing COPD.^[145]

Air pollution is further associated with increased risk of asthma and worsening of symptoms, and this effect seems stronger in children.^[146] For adults, fine particles (PM_2.5) or NO₂ seem linked to asthma onset too.^[147] Short-term exposure to ozone makes asthma worse in children.^[148] There is limited evidence on (almost) fatal asthma attacks in children: ground-level ozone and PM_2.5 seem to increase its risk.^[149]

The risk of lung disease from air pollution is greatest for 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 comorbidities.^[150]

Cancer

Around 265,000 lung cancer deaths were attributed globally in 2019 to exposure to fine particulate matter, PM_2.5, suspended in the air.^[151] Exposure to indoor air pollution, including radon, caused another 170,000 lung cancer deaths.^[151] Lung cancer was also more common among people exposed to NO₂ and black carbon.^[152]

Outdoor air pollution may increase risk of other types of cancer too, but the evidence is not as clear as for lung cancer.^[153] For instance, there may be a relationship between kidney cancer and PM_2.5 and NO₂ levels.^[154] Household air pollution, for instance from cooking with solid fuels, but also from radon in building material, has been associated with cervical, oral, and esophageal cancer.^[153]

Pregnancy and children

Stillbirths, miscarriages and birth defects are all more likely when the mother is exposed to air pollution during pregnancy. Exposure to air pollution also raises the chance a baby has a low birth weight. The impacts might be due to pollutants directly impacting the placenta or fetus, or indirectly as via the mother's health (as air pollution can cause systemic inflammation and oxidative stress).^[117]

Over a third of preterm births were associated with air pollution in 2021 globally. It causes more than half a million newborn deaths, a quarter of overall deaths.^[117] The source of PM_2.5 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.^[155]

Including older children, polluted air leads resulted in the death of over 700,000 children in 2021 (709,000 under 5 years of age and 16,600 aged 5–14 years).^[117] Children in low or middle income countries are exposed to higher levels of fine particulate matter than those in high income countries.^[156] Further health effects of air pollution on children include asthma, pneumonia and lower respiratory tract infections.^[157] There is possibly a link between exposure to air pollution during pregnancy and after birth and autism in children.^[158][159]

Brain health

Air pollution is linked to various diseases of the brain.^[114] Indoor air pollution exposure during childhood may negatively affect cognitive function and neurodevelopment.^[160][161] Prenatal exposure may also affect neurodevelopment.^[162][163] It may also contribute to neurodegenerative diseases such as Alzheimer's disease and Parkinson's disease.^[161] There are various routes by which air pollution could cause brain damage: it can cause neuroinflammation, or secondary effects from lung inflammation. At the same time, it can cause cardiovascular disease which in itself raises the risk of brain diseases.^[114]

Exposure to air pollution may also drive mental health issues, such as depression and anxiety.^[164] In particular, air pollution from the use of solid fuels was associated with a higher depression risk.^[165] Depression risk and suicide was more strongly linked to finer particulate matter (PM2.5), compared to coarser particles (PM10). The association was strongest for people over the age of 65.^[166]

Problems with thinking (cognitive issues) are also associated with air pollution. In people over the age of 40, both NO_x and PM_2.5 have been linked to general cognitive problems. PM_2.5 was also associated with reduced verbal fluency (for instance, number of animals one can list in a minute) and worse executive functions (like attention and working memory). Similarly, children tended to fare worse in tests involving working memory when there was NO_x, PM_2.5, or PM₁₀ pollution.^[167]

Monitoring

Air pollution can be monitored using different techniques. For instance, satellites and remote sensing is used to track PM, NO₂ and ozone.^[185] Many regions have a network of monitoring stations, with good coverage in India, China, Europe and the US. Poor coverage exist however for a number of highly-polluted countries, such as Chad and Iran. The density of measurements is improving as there are more low-cost techniques to measure air pollution.^[186] Low-cost monitors can also be used for indoor air quality monitoring.^[187] Finally, air quality sensors can be incorporated into drones to measure air pollution higher up in the air.^[188] Some websites attempt to map air pollution levels using available data.^[189][190]

Air quality indexes

Air quality indexes (AQIs) offer a simple way for governments to communicate changes in air quality and associated health risks, especially during short-term pollution episodes, such as wildfires.^[191] An AQI is essentially a health protection tool people can use to help reduce their short-term exposure to air pollution by adjusting activity levels during increased levels of air pollution. Examples include Canada's Air Quality Health Index (AQHI),^[192] Malaysia's Air Pollution Index, and Singapore's Pollutant Standards Index.

Emission factors

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.^{[3][193][194][195]} 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.

The United States Environmental Protection Agency has published a compilation of air pollutant emission factors for a wide range of industrial sources.^[197] The United Kingdom, Australia, Canada, and many other countries have published similar compilations, as well as the European Environment Agency.^{[198][199][200][201]}

Industry

Various pollution control technologies and strategies are available to reduce air pollution. For instance, industrial plants can install scrubbers, such as flue gas desulfurization or catalysts to remove NO_x.^[205] 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.^[206]

In the power sector, a very effective means to reduce air pollution is the transition to renewable energy or nuclear power.^[205] According to 2015 study 2015 the switch to 100% renewable energy in the United States would eliminate about 62,000 premature deaths 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.^[207]

Transport

The avoid-shift-improve framework groups efforts to cut pollution from vehicles into reducing travel, shifting to sustainable transport, and improving vehicle technology.^[208] Reducing motor vehicle travel can curb pollution. One strategy is to build compact cities, so that amenities are close by and cars are not needed.^[209] Motor traffic can be reduced by creating more walkable cities and by investing in cycling infrastructure.^[210] Working from home is another way of avoiding motorised traffic.^[208] After Stockholm reduced motor vehicle traffic in the central city with a congestion tax, nitrogen dioxide and PM₁₀ pollution declined, as did acute asthma attacks in children.^[211]

Traffic can be shifted to cleaner modes of transport, for instance by increased use of public transport.^[212][213] 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 CO₂ emissions during its three-month implementation from June to August 2022.^[214]

Finally, road vehicles can be improved from increased fuel efficiency, conversion to cleaner fuels, and conversion to electric vehicles. For example, buses in New Delhi, India, have run on compressed natural gas since 2000, to help eliminate the city's "pea-soup" smog.^[157][215] Phase-out of fossil fuel vehicles is a critical component of a shift to sustainable transport. However, even in electric vehicles, rubber tires produce significant amounts of air pollution, ranking as 13th worst pollutant in Los Angeles.^[216]

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.^[217] 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).^[218]

Cooking and heating

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.^[219][220] Biodigesters can be used 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.^[221]

Combustion of fossil fuels for space heating can be replaced by using heat pumps and seasonal thermal energy storage.^[222][223]

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.^[224]

Waste and agriculture

A growing number of countries regulates waste, which include national or city-wide waste management systems, opening managed landfills, landfill gas capture (for electricity production), and waste separation.^[44]

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).

Campaigning, public awareness and litigation

In 2022, the UN General Assembly passed a resolution recognizing the right to a clean, healthy, and sustainable environment as a human right.^[225]

In the United Kingdom, air pollution campaigning currently involves a mixture of grassroots activism (by groups such as Mums for Lungs and individual campaigners such as Rosamund Kissi-Debrah^[226]), public health awareness (through events such as Clean Air Day), legal work (advanced by activist lawyers such as ClientEarth), and more traditional campaigning (by environmental groups such as Greenpeace and Friends of the Earth, public health advocacy groups such as British Lung Foundation and Asthma UK, and organizations that raise health and safety issues, such as the British Safety Council).^[227] Citizen science projects combine scientific research with public health awareness raising and grassroots environmental campaigning.^[228]

In 2019, the Court of Justice of the EU, found that France did not comply with the limit values of the EU air quality standards applicable to the concentrations of nitrogen dioxide (NO₂) in 12 air quality zones.^[229]

Laws and regulations

Although a majority of countries have air pollution laws, 43% of countries lack a legal definition of air pollution, 34% lack outdoor air quality standards, and just 31% have laws for tackling pollution originating from outside their borders. Few countries have limits that are as strict as the World Health Organisation's recommendations.^[230]

Some air pollution laws include specific air quality standards, such as the U.S. National Ambient Air Quality Standards and E.U. Air Quality Directive,^[231] which specify maximum atmospheric concentrations for specific pollutants. Other examples of air quality laws around the world include the Clean Air Act in Britain, the US Clean Air Act, and TA Luft in Germany.^[232] Some air pollution laws put limits on emissions (e.g. from vehicles), as well as air standards.^[233]

The World Health Organization's Global Air Quality Guidelines encourage improvements in a similar way to national standards, but are "recommendations" and "good practice" rather than mandatory targets that countries must achieve.^[234]

Best practices

Cities and towns often work together, both nationally and internationally, to share best practices for improving air quality. Initiatives of this kind include the BreatheLife Network of 79 cities (a campaign launched in 2016 by the Climate and Clean Air Coalition, World Health Organization, United Nations Environment Programme, and World Bank),^[235] World Cities Day and the International Day of Clean Air for Blue Skies (two UN initiatives), and the Partnership for Healthy Cities (sponsored by the World Health Organization and health organization Vital Strategies).^[236]

Other networks include the C40 Cities Climate Leadership Group, a public 'non-state' network of the world's leading cities that aims to curb their greenhouse emissions.^[237] The C40 has been identified as 'governance from the middle' and is an alternative to intergovernmental policy.^[238] 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".^[237] 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.

Indigenous people

Because Indigenous people^[239] frequently experience a disproportionate share of the effects of environmental degradation and climate change, even while they have made very little contribution to the processes causing these changes, environmental justice is especially important to them. Indigenous peoples have been marginalized and their lands and resources have been exploited as a result of historical and continuing colonization, institutional injustices, and inequality.

Indigenous groups frequently lack the political and financial clout to influence policy decisions that impact their lands and means of subsistence or to lessen the effects of climate change. This makes the already-existing inequalities in these communities' social, economic, and health conditions worse. Furthermore, traditional ecological knowledge and Indigenous knowledge systems provide insightful information about sustainable resource management and climate change adaptation techniques. To promote persistence and environmental justice, Indigenous viewpoints must be acknowledged and integrated into efforts to mitigate the effects of climate change and adapt to them.

Combating climate change necessitates an all-encompassing strategy that recognizes the interdependence of social, economic, and environmental elements. This entails defending treaty rights, advancing Indigenous sovereignty and self-determination, and aiding Indigenous-led projects for sustainable development and environmental preservation.

Cities

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 air pollution in fast-growing tropical cities.^[247] However, even populated areas in developed countries have unhealthy levels of pollution, with Los Angeles and Rome being two examples.^[248] 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 .^[249]

Tehran was declared the most polluted city in the world on May 24, 2022.^[251]