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Atmospheric pollutants II
Oxides of nitrogen
Emissions are primarily in the form of NO, which is oxidised by ozone (O3) from nitric oxide to NO2. Nitrogen dioxide (NO2) is the primary concern for effects on health. The various oxides of nitrogen can also react with hydrocarbons in the atmosphere to contribute to photochemical smog. Oxides of nitrogen can also affect ecologically sensitive sites through deposition, causing acidification. The term nitrogen oxide can be used to refer to any of these oxides (oxygen compounds) of nitrogen: Nitric oxide (NO); Nitrogen dioxide (NO2); Dinitrogen oxide (N2O) (Nitrous oxide); Dinitrogen trioxide (N2O3); Dinitrogen tetroxide (N2O4); Dinitrogen pentoxide (N2O5). A mixture is often formed in chemical reactions that produce nitrogen oxides, with the proportions depending on the specific reaction and the conditions it is performed in. When dissolved in atmospheric moisture the result can be acid rain which can damage both trees and entire forest ecosystems.In atmospheric science the term NOx is used to mean the total concentration of NO plus NO2. During daylight NO and NO2 are in equilibrium with the ratio NO/NO2 determined by the intensity of sunshine (which converts NO2 to NO) and ozone (which reacts with NO to give back NO2). Three primary sources of Oxides of nitrogen formation in combustion processes are: prompt NO, fuel NO and thermal NO. Thermal NOx formation is recognized as the most relevant source when combusting natural gas.
Acid rain
Acid rain is defined as rain with a pH of below 5.6. Normal rain has a pH of slightly under 6, which is slightly acidic. This natural acidity is caused by dissolved carbon dioxide. Acid rain is caused by sulfur from impurities in fossil fuels and nitrogen from the air combining with oxygen to form sulfur dioxide and nitrogen oxides. These diffuse into the atmosphere and react with air to form sulfuric and nitric acids which are soluble and fall with the rain. Some The resulting increased acidity in soil has proven to be harmful to vegetation. Principal sources are industrial and power-generating plants and transportation vehicles. The gases may be carried hundreds of miles in the atmosphere before they are converted to acids and deposited. Since the industrial revolution, emissions of sulfur and nitrogen oxides to the atmosphere have increased. Industrial and energy-generating facilities that burn fossil fuels, primarily coal, are the principal sources of increased sulfur oxides. The toxic ions released due to acid rain form the greatest threat to humans.
Organic pollutants
Volatile organic compounds are organic chemical compounds that have high enough vapour pressures under normal conditions to significantly vaporize and enter the atmosphere. A wide range of carbon-based molecules, such as aldehydes, are volatile organic compounds. Common artifical sources of volatile organic compounds include paint thinners, dry cleaning solvents, and some constituents of petroleum fuels. Volatile organic compounds are an important outdoor air pollutant. In this field they are often divided up into the separate categories of methane (CH4) and non-methane. Methane is an extremely efficient greenhouse gas which may contribute to enhanced global warming. Within the non-methanes, benzene may lead to leukaemia through prolonged exposure. 1,3-butadiene is another dangerous compound which is often associated with industrial uses. Volatile organic compounds are often used in paint, plastics, and cosmetics.
Photochemical smog
Photochemical smog is caused when two kinds of air pollution combine in the presence of sunlight. The first kind is the particulates and nitric oxides from the exhaust of fossil fuel-burning engines in cars and coal power plants. The second kind is the emission of volatile organic compounds from paints, solvents, and other chemicals. Smog is a problem in a number of cities and continues to harm life. High levels of smog aggravate and even cause human respiratory problems.
Emissions I - Emissions II - Emissions III - Pollutants I - Pollutants II
Pollution map (XY-Plane) produced by continuous discharge in a road region. The red colour represents high pollutant concentrations. Wind: SW (225 degrees).
Air pollution map (XY-Plane) produced by continuous discharge in time. The fucshia lines represents a stacks in the XY-Plane. The red colour represents high pollutant concentrations. Winds: E (90 dregrees) and S (180 degrees).
Canarina Algoritmos Numéricos, S.L.
Environmental software solutions
Software para impacto del medio ambiente
Canary Islands, Spain
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European network on pollution · European Union
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flow rate modeling
CANARINA: Home - Air pollution · DISPER - Noise pollution · CUSTIC - Water pollution · DESCAR - Contact us
DISPER: Air pollution dispersion · DISPER - Solutions - Data - Algorithms - Emissions - Graphs - ISC3 (VOL. 2)
SOLUTIONS: Air pollution dispersion · DISPER - Software solutions - Software advantages - Price - DEMO download
COMMANDS: Input data I - Input data II - Input data III - Input data IV - Temporal average - Import and export data - Software commands
ALGORITHMS: Algorithms I - Algorithms II - Algorithms III - Algorithms IV - Algorithms V - Algorithms VI - Algorithms VII - Algorithms VIII - Algorithms IX - Algorithms X
EMISSIONS: Emissions I - Emissions II - Emissions III - Pollutants I - Pollutants II
GRAPHS: Graphs I - Graphs II - Graphs III - Graphs IV
DISPER software solutions: This application has been used in great number of environmental reports, air pollution courses and air pollution studies in the last years. We currently have users in more than 10 countries.
Somerset -
air pollution cars - air pollution from cars - car air pollution
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cars and air pollution - air pollution caused by cars - air pollution by cars -
car air quality - air pollution from car - cars cause air pollution -
Essex - car exhaust air pollution - air pollution by car -
Kent - zero air pollution cars - air quality tests
Staffordshire - cars contribute to air pollution - air pollution caused by car -
Lancashire - car cabin air quality - hybrid cars air pollution -
Gloucestershire - air fuel cars - air quality tests
Cornualles - air gas - air quality tests
Hampshire - air pollution comparison -
Suffolk - pollution causes - air quality tests
Cambridgeshire - motor vehicle air pollution -
Northumberland - air pollution due to vehicles - vehicle emissions air quality - vehicle emissions air quality uk -
Cumbria - on the costs of air pollution from motor vehicles -
Shropshire - environmental pollution - air quality tests
Devon - air pollution co2 - air pollution dust - air pollution exhaust -
Lincolnshire - air pollution reduction - air quality tests
Wiltshire - air pollution traffic - air pollution particles - air pollution so2 -
North Yorkshire - industry pollution - air pollution atmospheric - air pollution transport -
Norfolk - air pollution concentrations - air pollution level - air pollution study -
Aberdeen - air pollution particulate - air pollution urban - air pollution permit -
Armagh - air pollution burning - air pollution sulfur - pollution source -
Bangor - air pollution carbon - automobile vehicle
Bath - air pollution pm - vehicle cars - pollution sources -
Belfast - air pollution inventory - control pollution - report pollution -
Chichester - dispersion simulation - water gas - particle dispersion -
City of London - dispersion method - thermal dispersion - filter dispersion -
Coventry - oil dispersion - gas modeling - velocity dispersion -
Derby - carbon dioxide dispersion - industrial dispersion -
Derry - diesel gas - gas dynamics - gas filtration -
Dundee - temperature dispersion - turbulence dispersion - flow dispersion -
Gloucester - gas dispersion tubes - gas dispersion modeling - gas dispersion frit -
Hereford - heavy gas dispersion - dense gas dispersion model -
Kingston upon Hull - co2 dispersion - dispersion modeling - nitrogen gas -
Lancaster - gas density - solid dispersion - oxygen gas -
Leeds - gas epa - wind dispersion - dispersion models -
Leicester - air pollution dispersion - water dispersion - gas simulation -
Lichfield - gas diffusion - gas stability - gas design -
Lincoln - gas plume - gas models - dispersion modelling -
Newry - numerical dispersion - plant dispersion - gas membrane -
Norwich - gas pollution - plume dispersion - dispersion diffusion -
Nottingham - vacuum dispersion - data dispersion - gas equations -
Oxford - model dispersion - gas calculation - gas air pollution -
Peterborough - gas dispersion software - air gas - dispersion fluid -
Stirling - chemical dispersion - dispersion theory - dispersion calculation -
Stoke-on-Trent - heat dispersion - hydrogen dispersion - dispersion air -
Swansea - gas forces - dispersion equation - gas distillation -
Wells - gas dispersion model - fundamentals of stack gas dispersion -
Winchester - dense gas dispersion - stack gas dispersion - dispersion fuel -
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