17 Air Pollution

    Structure:   

 

1.1       Introduction

 

1.2       Factors Likely to increase the Levels of Air Pollution

 

1.3       Tpes of Air Pollution

 

1.3.1    The Major Pollutants

 

1.4       Sources of Air Pollution

 

1.5       Air Pollution Impacts on People and Enviornment

 

1.5.1     Air Pollution Impacts on health of people

 

1.5.2     Effects on Animals and Plants

 

1.5.3    Effects of Air Pollutants on Materials

 

1.5.4    Other effects of Air Pollution

 

1.6       Control of Air Pollution

 

1.7       Conclusion

 

 

Objectives

 

1.1 Introduction

 

The air we breathe is an essential ingredient for our wellbeing and a healthy life. Unfortunately air has been polluted. There is no doubt that air pollution existed in ancient times, but it was much less severe and less widespread than today. Three factors account for this, (i) less human population, (ii) small consumption per person and (iii) very basic types of materials used. Today, however, it has reached massive proportions and threatens to change the global environment. According to Mishra (2003) rapid growth in urban population, increasing industrialization, and rising demands for energy and motor vehicles are the worsening air pollution levels. He added other factors, such as poor environmental regulation, less efficient technology of production, congested roads, and age and poor maintenance of vehicles, also add to the problem. He further added that air pollution is caused of ill health and death by natural and man-made sources, major man-made sources of ambient air pollution include tobacco smoke, combustion of solid fuels for cooking, heating, home cleaning agents, insecticides industries, automobiles, power generation, poor environmental regulation, less efficient technology of production, congested roads, and age and poor maintenance of vehicles. The natural sources include incinerators and waste disposals, forest and agricultural fires (European Public Health Alliance, 2009).The sources of air pollution are many and are often completely related to the environment. However, there is no doubt about the root cause: a world population of more than 7.5 billion growing by more than 80 million a year. Most of these people will be in developing countries where air pollution will likely reach unprecedented levels with higher levels of fossil – fuel burning relation to consumption of goods from factories, home heating, cooking and transportation. Approximately 50 – 70% of all air pollution arises from transportation-combustion sources, 15-25% from heavy industrial stationary sources and as much as 25% from other stationary sources.

 

“Air is polluted when one or several pollutants are present in the atmosphere at such a concentration and for so long a time that they are harmful to man, animals, plants or material property, cause harm or reduce well-being or disturb appreciably its application” (World Health Organisation).

 

“Any deviation from the natural combination of gases in our atmosphere” (NSW Protection of the Environment Operations Act). What this definition fails to mention is that the natural combination of gases in our atmosphere must be taken as dry air at sea level. This is necessary as it is not possible to quantitatively define pure air because it will change according to altitude and location. This also means that theoretically air pollution can also arise from the removal of gases from the atmosphere.

 

 

1.2 Factors Likely to Increase the Levels of Air Pollution

 

Certain conditions help make air pollution worse. Basically these are factors which prevent air circulation, and concentrate air effluent into areas. Examples of these include; calm conditions, low level emission sources, temperature inversions, buildings and narrow streets. By contrast other conditions are known to lower air pollution levels in general. These are those conditions that encourage circulation or remove pollutants from the atmosphere. These include windy or turbulent conditions, high levels of vegetation, high level emission sources such as smoke stacks and rain.

 

1.3 Types of Air Pollution

 

Air pollution occurs due to the presence of undesirable solid or gaseous particles in the air in quantities that are harmful to human health and the environment. Air may get polluted by natural causes such as volcanoes, which release ash, dust, sulphur and other gases, or by forest fires that are occasionally naturally caused by lightning. However, unlike pollutants from human activity, naturally occurring pollutants tend to remain in the atmosphere for a short time and do not lead to permanent atmospheric change.

 

Pollutants that are emitted directly from identifiable sources, produced both by natural events (for example, dust storms and volcanic eruptions) and human activities (emission from vehicles, industries, etc.) are referred to as primary pollutants. There are five primary pollutants that together contribute about 90 per cent of the global air pollution. These are carbon oxides, nitrogen oxides, sulfur oxides, volatile organic compounds (mostly hydrocarbons) and suspended particulate matter. Not all of the pollutants found in the atmosphere are the direct result of emissions. Many of the substances found in the atmospheres that are regarded as pollutants arise from chemical reactions in the atmosphere with other substances or light. Chemical reactions that require light in order to proceed are referred to as photochemical reactions. Those substances that are not directly emitted into the atmosphere, but rather are formed by chemical reactions in the atmosphere are referred to as secondary pollutants. Acid rain is a form of secondary pollution because it results from processes occurring within the atmosphere after primary pollutants such as SO2 are emitted from exhaust stacks and other sources.

Particulates: Particulate matter may be classified under the following headings: o Dusts – large solid particles (>100um) carried into the air.

 

• Fume – solid particles (frequently metallic oxides) formed by condensation of vapours from a chemical reaction process or physical separation process. These particles are typically between 0.03 – 0.3um in diameter.
• Mist – liquid particles formed by condensation of vapours or chemical reaction.
• Smoke – solid particles formed as a result of incomplete combustion of carbonaceous materials. Typical diameter is between 0.5 – 1.0um.
• Spray – a liquid particle formed by the atomisation of a parent liquid.

 

1.5.2 Effects on Animals and Plants

 

The impact of air pollution on animals is more or less similar to that on man. Chronic poisoning results from the ingestion of forage contaminated with atmospheric pollutants. Fluoride causes fluorosis among animals. A number of livestock have been poisoned by fluorides and arsenic in North America. Bone lesions in animals due to excessive fluorides have also been reported.

 

Air pollution has caused widespread damage to trees, fruits, vegetables, flowers and in general, vegetation as a whole. The total annual cost of plant damage caused by air pollution in USA alone has been estimated to be in the range of 1 to 2 billion dollars. The most dramatic early instances of plant damage were seen in the total destruction of vegetation by SO2 in the areas surrounding smelters. When the absorption of SO2 exceeds a particular level, the cells become inactive and are killed, resulting in tissue collapse and drying of leaves. Cotton, wheat, barley and apple are more sensitive to this pollutant. The leaves of apple, apricot, fig, peach and prune are more susceptible to air borne fluorides. Fluorides seem to interfere with the photosynthesis and respiration of plants.

 

1.5.3    Effects of Air Pollutants on Materials

 

Air pollutants produce physical and chemical change in materials which results in their damage and destruction. The natural effects of corrosion and weathering are aggravated when the air is polluted. The most destructive air pollutants to materials are smoke, grit, dust and oxides of sulphur. SO2 changes to sulfurous and sulphuric acid with moisture and accelerates the rate of corrosion. Different types of metals and metallic structures such as iron and steel, aluminium and aluminium alloys, copper and copper alloys are corroded when exposed to polluted air. Building materials are also corroded and disfigured with increasing pollution of air. In 1972, when an oil refinery at Mathura was opened, its impact on Taj Mahal became a major issue. Smoke, grit and soot deposits disfigure the buildings.

 

1.5.4 Other Effects of Air Pollution

 

(a) Global warming: Another direct effect of air pollution is the immediate alterations that the world is witnessing due to Global warming. With increased temperatures worldwide, increase in sea levels and melting of ice from colder regions and icebergs, displacement and loss of habitat have already signaled an impending disaster if actions for preservation and normalization aren’t undertaken soon.

 

(b) Ozone depletion: Ozone is a gas that occurs both at ground-level and in the Earth’s upper atmosphere, known as the stratosphere. At ground level, ozone is a pollutant that can harm human health. In the stratosphere, however, ozone forms a layer that protects life on earth from the sun’s harmful ultraviolet (UV) rays. But this ozone is gradually being destroyed by man-made chemicals referred to as ozone-depleting substances, including chlorofluorocarbons, hydrochlorofluorocarbons, and halons. These substances were formerly used and sometimes still are used in coolants, foaming agents, fire extinguishers, solvents, pesticides, and aerosol propellants. Thinning of the protective ozone layer can cause increased amounts of UV radiation to reach the Earth, which can lead to more cases of skin cancer, cataracts, and impaired immune systems. UV can also damage sensitive crops, such as soybeans, and reduce crop yields.

 

(c) Acid Rain: Harmful gases like nitrogen oxides and sulfur oxides are released into the atmosphere during the burning of fossil fuels. When it rains, the water droplets combines with these air pollutants, becomes acidic and then falls on the ground in the form of acid rain. Acid rain can cause great damage to human, animals and crops.

 

(d) Eutrophication: Eutrophication is a condition where high amount of nitrogen present in some pollutants gets developed on sea’s surface and turns itself into algae and and adversely affect fish, plants and animal species. The green coloured algae that is present on lakes and ponds is due to presence of this chemical only.

 

 

1.6 Control of Air Pollution

 

Worldwide air pollution control remains a great uphill task and is certain to remain so for many decades. Air pollution control is pursued more or less at all scales from global to local including the home and at workplace. However, the effort is very spotty geographically with programs limited mostly to developed nations. Some of the effective methods to control air pollution are as follows:

 

(A)  Source Correction Methods

(B)  Pollution Control equipment

(C)  Diffusion of Pollutant in Air

(D)  Vegetation

(E)  Zoning.

 

(A) Source Correction Methods: Industries make a major contribution towards causing air pollution. Formation of pollutants can be prevented and their emission can be minimised at the source itself. By carefully investigating the early stages of design and development in industrial processes e.g., those methods which have minimum air pollution potential can be selected to accomplish air-pollution control at source itself. The source correction methods are:

 

(i) Substitution of raw materials: If the use of a particular raw material results in air pollution, then it should be substituted by another purer grade raw material which reduces the formation of pollutants. For example, low sulphur fuel can be used as an alternative to high sulphur fuels, and, comparatively more refined liquid petroleum gas (LPG) or liquefied natural gas (LNG) can be used instead of traditional high contaminant fuels such as coal.

 

(ii) Process Modification: The existing process may be changed by using modified techniques to control emission at source. For example, smoke, carbon-monoxide and fumes can be reduced if open hearth furnaces are replaced with controlled basic oxygen furnaces or electric furnaces. In petroleum refineries, loss of hydrocarbon vapours from storage tanks due to evaporation, temperature changes or displacement during filling etc. can be reduced by designing the storage tanks with floating roof covers. An appreciable amount of pollution is caused due to poor maintenance of the equipment which includes the leakage around ducts, pipes, valves and pumps etc. Emission of pollutants due to negligence can be minimised by a routine checkup of the seals and gaskets.

 

(B)  Pollution Control Equipment:

 

Sometimes pollution control at source is not possible by preventing the emission of pollutants. Then it becomes necessary to install pollution control equipment to remove the gaseous pollutants from the main gas stream. Pollution control equipments include,

 

(i) Gravitational Settling Chamber: For removal of particles exceeding 50 μm in size from polluted gas streams, gravitational settling chambers are put to use.

 

(ii) Cyclone Separators (Reverse flow Cyclone) :Instead of gravitational force, centrifugal force is utilized by cyclone separators, to separate the particulate matter from the polluted gas.

 

(iii) Fabric Filters (Baghouse Filters): In a fabric filter system, a stream of the polluted gas is made to pass through a fabric that filters out the particulate pollutant and allows the clear gas to pass through. The particulate matter is left in the form of a thin dust mat on the insides of the bag. This dust mat acts as a filtering medium for further removal of particulates increasing the efficiency of the filter bag to sieve more sub-micron particles.