In
environmental science
Environmental science is an interdisciplinary academic field that integrates physics, biology, and geography (including ecology, chemistry, plant science, zoology, mineralogy, oceanography, limnology, soil science, geology and physical geograp ...
, air pollution dispersion is the distribution of
air pollution into the
atmosphere
An atmosphere () is a layer of gas or layers of gases that envelop a planet, and is held in place by the gravity of the planetary body. A planet retains an atmosphere when the gravity is great and the temperature of the atmosphere is low. A s ...
. ''Air pollution'' is the introduction of
particulates, biological molecules, or other harmful materials into Earth's atmosphere, causing
disease, death to humans, damage to other living organisms such as food crops, and the
natural or
built environment. Air pollution may come from
anthropogenic
Anthropogenic ("human" + "generating") is an adjective that may refer to:
* Anthropogeny, the study of the origins of humanity
Counterintuitively, anthropogenic may also refer to things that have been generated by humans, as follows:
* Human im ...
or natural sources. ''Dispersion'' refers to what happens to the pollution during and after its introduction; understanding this may help in identifying and controlling it.
Air pollution dispersion has become the focus of
environmental conservationists and governmental
environmental protection agencies (local, state, province and national) of many countries (which have adopted and used much of the terminology of this field in their laws and regulations) regarding
air pollution control.
Air pollution emission plumes
Air pollution emission plume
The atmosphere of Earth is the layer of gases, known collectively as air, retained by Earth's gravity that surrounds the planet and forms its planetary atmosphere. The atmosphere of Earth protects life on Earth by creating pressure allowing for ...
– flow of pollutant in the form of vapor or smoke released into the air. Plumes are of considerable importance in the atmospheric dispersion modelling of air pollution. There are three primary types of air pollution
emission
Emission may refer to:
Chemical products
* Emission of air pollutants, notably:
**Flue gas, gas exiting to the atmosphere via a flue
** Exhaust gas, flue gas generated by fuel combustion
** Emission of greenhouse gases, which absorb and emit radi ...
plumes:
*
Buoyant plumes — Plumes which are lighter than air because they are at a higher
temperature and lower
density than the ambient air which surrounds them, or because they are at about the same temperature as the ambient air but have a lower
molecular weight and hence lower density than the ambient air. For example, the emissions from the
flue gas stacks
A flue-gas stack, also known as a smoke stack, chimney stack or simply as a stack, is a type of chimney, a vertical pipe, channel or similar structure through which combustion product gases called flue gases are exhausted to the outside air. Flue ...
of industrial
furnaces are buoyant because they are considerably warmer and less dense than the ambient air. As another example, an emission plume of
methane gas at ambient air temperatures is buoyant because methane has a lower molecular weight than the ambient air.
*
Dense gas plumes — Plumes which are heavier than air because they have a higher density than the surrounding ambient air. A plume may have a higher density than air because it has a higher molecular weight than air (for example, a plume of
carbon dioxide). A plume may also have a higher density than air if the plume is at a much lower temperature than the air. For example, a plume of
evaporated gaseous methane from an accidental release of
liquefied natural gas (LNG) may be as cold as -161 °C.
* Passive or neutral plumes — Plumes which are neither lighter or heavier than air.
Air pollution dispersion models
There are five types of air pollution dispersion models, as well as some hybrids of the five types:
* Box model — The box model is the simplest of the model types. It assumes the
airshed (i.e., a given volume of
atmospheric
An atmosphere () is a layer of gas or layers of gases that envelop a planet, and is held in place by the gravity of the planetary body. A planet retains an atmosphere when the gravity is great and the temperature of the atmosphere is low. A s ...
air in a geographical region) is in the shape of a box. It also assumes that the air pollutants inside the box are homogeneously distributed and uses that assumption to estimate the average pollutant
concentrations anywhere within the airshed. Although useful, this model is very limited in its ability to accurately predict dispersion of air pollutants over an airshed because the assumption of homogeneous pollutant distribution is much too simple.
*
Gaussian model — The Gaussian model is perhaps the oldest (circa 1936) and perhaps the most commonly used model type. It assumes that the air pollutant dispersion has a
Gaussian distribution, meaning that the pollutant distribution has a normal probability distribution. Gaussian models are most often used for predicting the dispersion of continuous, buoyant air pollution plumes originating from ground-level or elevated sources. Gaussian models may also be used for predicting the dispersion of non-continuous air pollution plumes (called ''puff models''). The primary algorithm used in Gaussian modeling is the ''Generalized Dispersion Equation For A Continuous Point-Source Plume''.
[ (Chapter 8, page 124)]
*
Lagrangian
Lagrangian may refer to:
Mathematics
* Lagrangian function, used to solve constrained minimization problems in optimization theory; see Lagrange multiplier
** Lagrangian relaxation, the method of approximating a difficult constrained problem with ...
model — a Lagrangian dispersion model mathematically follows pollution plume parcels (also called particles) as the parcels move in the atmosphere and they model the motion of the parcels as a
random walk process. The Lagrangian model then calculates the air pollution dispersion by computing the statistics of the trajectories of a large number of the pollution plume parcels. A Lagrangian model uses a moving
frame of reference
In physics and astronomy, a frame of reference (or reference frame) is an abstract coordinate system whose origin, orientation, and scale are specified by a set of reference points― geometric points whose position is identified both mathema ...
[Features of Dispersion Models]
publication of the European Union Joint Research Centre (JRC) as the parcels move from their initial location. It is said that an observer of a Lagrangian model follows along with the plume.
*
Eulerian model — an Eulerian dispersion model is similar to a Lagrangian model in that it also tracks the movement of a large number of pollution plume parcels as they move from their initial location. The most important difference between the two models is that the Eulerian model uses a fixed three-dimensional
Cartesian grid[ as a frame of reference rather than a moving frame of reference. It is said that an observer of an Eulerian model watches the plume go by.
*Dense gas model — Dense gas models are models that simulate the dispersion of dense gas pollution plumes (i.e., pollution plumes that are heavier than air). The three most commonly used dense gas models are:
**The DEGADIS model developed by Dr. Jerry Havens and Dr. Tom Spicer at the University of Arkansas under commission by the US Coast Guard and US EPA.
** The SLAB model developed by the ]Lawrence Livermore National Laboratory
Lawrence Livermore National Laboratory (LLNL) is a federal research facility in Livermore, California, United States. The lab was originally established as the University of California Radiation Laboratory, Livermore Branch in 1952 in response ...
funded by the US Department of Energy, the US Air Force and the American Petroleum Institute.
** The HEGADAS model developed by Shell Oil
Shell plc is a British multinational oil and gas company headquartered in London, England. Shell is a public limited company with a primary listing on the London Stock Exchange (LSE) and secondary listings on Euronext Amsterdam and the New Yor ...
's research division.
Air pollutant emission
* Types of air pollutant emission sources – named for their characteristics
** Sources, by shape – there are four basic shapes which an emission source may have. They are:
*** Point source — single, identifiable source of air pollutant emissions (for example, the emissions from a combustion furnace flue gas stack). Point sources are also characterized as being either elevated or at ground-level. A point source has no geometric
Geometry (; ) is, with arithmetic, one of the oldest branches of mathematics. It is concerned with properties of space such as the distance, shape, size, and relative position of figures. A mathematician who works in the field of geometry is ca ...
dimensions.
*** Line source — one-dimensional source of air pollutant emissions (for example, the emissions from the vehicular traffic
In mathematics and transportation engineering, traffic flow is the study of interactions between travellers (including pedestrians, cyclists, drivers, and their vehicles) and infrastructure (including highways, signage, and traffic control devi ...
on a roadway).
*** Area source — two-dimensional source of diffuse air pollutant emissions (for example, the emissions from a forest fire
A wildfire, forest fire, bushfire, wildland fire or rural fire is an unplanned, uncontrolled and unpredictable fire in an area of Combustibility and flammability, combustible vegetation. Depending on the type of vegetation present, a wildfire ...
, a landfill
A landfill site, also known as a tip, dump, rubbish dump, garbage dump, or dumping ground, is a site for the disposal of waste materials. Landfill is the oldest and most common form of waste disposal, although the systematic burial of the waste ...
or the evaporated vapors from a large spill of volatile liquid).
*** Volume source — three-dimensional source of diffuse air pollutant emissions. Essentially, it is an area source with a third (height) dimension (for example, the fugitive gaseous emissions from piping flanges, valves and other equipment at various heights within industrial facilities such as oil refineries and petrochemical plants). Another example would be the emissions from an automobile paint shop with multiple roof vents or multiple open windows.
** Sources, by motion
*** Stationary source – flue gas stacks are examples of stationary sources
*** Mobile source – bus
A bus (contracted from omnibus, with variants multibus, motorbus, autobus, etc.) is a road vehicle that carries significantly more passengers than an average car or van. It is most commonly used in public transport, but is also in use for cha ...
es are examples of mobile sources
** Sources, by urbanization level – whether the source is within a city or not is relevant in that urban areas constitute a so-called ''heat island'' and the heat rising from an urban area causes the atmosphere above an urban area to be more turbulent than the atmosphere above a rural area
*** Urban source – emission is in an urban area
*** Rural source – emission is in a rural area
** Sources, by elevation
*** Surface or ground-level source
*** Near surface source
*** Elevated source
** Sources, by duration
*** Puff or intermittent source – short term sources (for example, many accidental emission releases are short term puffs)
*** Continuous source – long term source (for example, most flue gas stack emissions are continuous)
Characterization of atmospheric turbulence
Effect of turbulence on dispersion – turbulence increases the entrainment and mixing of unpolluted air into the plume and thereby acts to reduce the concentration of pollutants in the plume (i.e., enhances the plume dispersion). It is therefore important to categorize the amount of atmospheric turbulence present at any given time. This type of dispersion is scale dependent. Such that, for flows where the cloud of pollutant is smaller than the largest eddies present, there will be mixing. There is no limit on the size on mixing motions in the atmosphere and therefore bigger clouds will experience larger and stronger mixing motions. And hence, this type of dispersion is scale dependent.
The Pasquill atmospheric stability classes
Pasquill atmospheric stability classes – oldest and, for a great many years, the most commonly used method of categorizing the amount of atmospheric turbulence present was the method developed by Pasquill in 1961.
He categorized the atmospheric turbulence into six stability classes named A, B, C, D, E and F with class A being the most unstable or most turbulent class, and class F the most stable or least turbulent class.
* Table 1 lists the six classes
* Table 2 provides the meteorological conditions that define each class. The stability classes demonstrate a few key ideas. Solar radiation increases atmospheric instability through warming of the Earth's surface so that warm air is below cooler (and therefore denser) air promoting vertical mixing. Clear nights push conditions toward stable as the ground cools faster establishing more stable conditions and inversions. Wind increases vertical mixing, breaking down any type of stratification and pushing the stability class towards neutral (D).
Table 1: The Pasquill stability classes
Table 2: Meteorological conditions that define the Pasquill stability classes
Incoming solar radiation is based on the following: strong (> 700 W m−2), moderate (350-700 W m−2), slight (< 350 W m−2)
Other parameters that can define the stability class
The stability class can be defined also by using the
* Temperature gradient
* fluctuations in wind direction
* Richardson number
* Bulk Richardson number
* Monin–Obukhov length
/ref>
Advanced methods of categorizing atmospheric turbulence
Advanced air pollution dispersion models – they do not categorize atmospheric turbulence by using the simple meteorological parameters commonly used in defining the six Pasquill classes as shown in Table 2 above. The more advanced models use some form of Monin-Obukhov similarity theory. Some examples include:
* AERMOD The AERMOD atmospheric dispersion modeling system is an integrated system that includes three modules:Prater, E.T. and Midgley, C., ''A new air dispersion modeling system is helping create more accurate industrial source models'', Environmental Pro ...
– US EPA's most advanced model, no longer uses the Pasquill stability classes to categorize atmospheric turbulence. Instead, it uses the surface roughness length and the Monin-Obukhov length.
* ADMS 4 The ADMS 3 (Atmospheric Dispersion Modelling System) is an advanced atmospheric pollution dispersion model for calculating concentrations of atmospheric pollutants emitted both continuously from point, line, volume and area sources, or intermit ...
[ADMS 4]
Description of the model by the developers, Cambridge Environmental Research Consultants. – United Kingdom's most advanced model, uses the Monin-Obukhov length, the boundary layer height and the windspeed to categorize the atmospheric turbulence.
Miscellaneous other terminology
::''(Work on this section is continuously in progress)''
*Building effects or downwash: When an air pollution plume flows over nearby buildings or other structures, turbulent eddies are formed in the downwind side of the building. Those eddies cause a plume from a stack source located within about five times the height of a nearby building or structure to be forced down to the ground much sooner than it would if a building or structure were not present. The effect can greatly increase the resulting near-by ground-level pollutant concentrations downstream of the building or structure. If the pollutants in the plume are subject to depletion by contact with the ground ( particulates, for example), the concentration increase just downstream of the building or structure will decrease the concentrations further downstream.
* Deposition of the pollution plume components to the underlying surface can be defined as either dry or wet deposition:
**Dry deposition is the removal of gaseous or particulate material from the pollution plume by contact with the ground surface or vegetation (or even water surfaces) through transfer processes such as absorption
Absorption may refer to:
Chemistry and biology
* Absorption (biology), digestion
**Absorption (small intestine)
*Absorption (chemistry), diffusion of particles of gas or liquid into liquid or solid materials
*Absorption (skin), a route by which ...
and gravitational sedimentation. This may be calculated by means of a '' deposition velocity'', which is related to the resistance of the underlying surface to the transfer.
**Wet deposition is the removal of pollution plume components by the action of rain. The wet deposition of radionuclides in a pollution plume by a burst of rain often forms so called ''hot spots'' of radioactivity on the underlying surface.
* Inversion layers:[ Normally, the air near the Earth's surface is warmer than the air above it because the atmosphere is heated from below as solar radiation warms the Earth's surface, which in turn then warms the layer of the atmosphere directly above it. Thus, the atmospheric temperature normally decreases with increasing altitude. However, under certain meteorological conditions, atmospheric layers may form in which the temperature increases with increasing altitude. Such layers are called inversion layers. When such a layer forms at the Earth's surface, it is called a surface inversion. When an inversion layer forms at some distance above the earth, it is called an inversion aloft (sometimes referred to as a '' capping inversion''). The air within an inversion aloft is very stable with very little vertical motion. Any rising parcel of air within the inversion soon expands, thereby adiabatically cooling to a lower temperature than the surrounding air and the parcel stops rising. Any sinking parcel soon compresses adiabatically to a higher temperature than the surrounding air and the parcel stops sinking. Thus, any air pollution plume that enters an inversion aloft will undergo very little vertical mixing unless it has sufficient ]momentum
In Newtonian mechanics, momentum (more specifically linear momentum or translational momentum) is the product of the mass and velocity of an object. It is a vector quantity, possessing a magnitude and a direction. If is an object's mass an ...
to completely pass through the inversion aloft. That is one reason why an inversion aloft is sometimes called a capping inversion.
*Mixing height:[ When an inversion aloft is formed, the atmospheric layer between the Earth's surface and the bottom of the inversion aloft is known as the mixing layer and the distance between the Earth's surface and the bottom of inversion aloft is known as the mixing height. Any air pollution plume dispersing beneath an inversion aloft will be limited in vertical mixing to that which occurs beneath the bottom of the inversion aloft (sometimes called the ''lid''). Even if the pollution plume penetrates the inversion, it will not undergo any further significant vertical mixing. As for a pollution plume passing completely through an inversion layer aloft, that rarely occurs unless the pollution plume's source stack is very tall and the inversion lid is fairly low.
]
See also
Air pollution dispersion models
*ADMS 3 The ADMS 3 (Atmospheric Dispersion Modelling System) is an advanced atmospheric pollution dispersion model for calculating concentrations of atmospheric pollutants emitted both continuously from point, line, volume and area sources, or intermit ...
(Atmospheric Dispersion Modelling System) – advanced atmospheric pollution dispersion model for calculating concentrations of atmospheric pollutants emitted both continuously from point, line, volume and area sources, or intermittently from point sources.
*AUSTAL
*AERMOD The AERMOD atmospheric dispersion modeling system is an integrated system that includes three modules:Prater, E.T. and Midgley, C., ''A new air dispersion modeling system is helping create more accurate industrial source models'', Environmental Pro ...
*CANARY (By Quest)
Canary originally referred to the island of Gran Canaria on the west coast of Africa, and the group of surrounding islands (the Canary Islands). It may also refer to:
Animals Birds
* Canaries, birds in the genera ''Serinus'' and ''Crithagra'' in ...
* CALPUFF
* DISPERSION21
* FLACS
*ISC3 ISC3 (Industrial Source Complex) model is a popular steady-state Gaussian plume model which can be used to assess pollutant concentrations from a wide variety of sources associated with an industrial complex.
This model can account for the followi ...
* MERCURE
* NAME (dispersion model)
* Panache
* PHAST
* PUFF-PLUME
* SIRANE
Others
*Bibliography of atmospheric dispersion modeling
Atmospheric dispersion modeling is the mathematical simulation of how air pollutants disperse in the ambient atmosphere. It is performed with computer programs that include algorithms to solve the mathematical equations that govern the pollutant ...
* AP 42 Compilation of Air Pollutant Emission Factors
* Atmospheric dispersion modeling
* Roadway air dispersion modeling
* Useful conversions and formulas for air dispersion modeling
* List of atmospheric dispersion models
* Yamartino method
* Air pollution forecasting
References
Further reading
www.crcpress.com
*
External links
Air pollution dispersion modeling terminology
A Citizendium article
Air Quality Models
(on the US EPA's website)
The Model Documententation System (MDS)
of the European Topic Centre on Air and Climate Change (part of the European Environment Agency
The European Environment Agency (EEA) is the agency of the European Union (EU) which provides independent information on the environment.
Definition
The European Environment Agency (EEA) is the agency of the European Union (EU) which provides i ...
)
{{DEFAULTSORT:Air Pollution Dispersion Terminology
Atmospheric dispersion modeling
Air pollution
Industrial emissions control
Environmental engineering
Air pollution