Master Basic EnvSci Notes PDF

Summary

This document provides basic notes on environmental science, including definitions, overviews, and historical contexts. It covers topics such as the environment's definition and the establishment of environmental departments in Malaysia, and the Brundtland Report.

Full Transcript

Definition of “Environment”

ENVIRONMENT means the physical factors of the
surroundings of the human beings including land, water,
atmosphere, climate, sound, odour, taste, the biological factors
of animals and plants and the social factor of aesthetics.
(Environmental Quality Act, 1974)
 OVERVIEW OF ENVIRONMENT & ITS RELATED ELEMENTS

Environment

Physical Chemical Biological Social Aesthetical

o Water
o Earth & o Ecological o Health & env.
atmosphere concept o Socio-politic &
o Sources & o Biogeochemical env.
processes of cycle o Env. Education
pollutants o Nat resources o Env. Regulation
(rivers, wetland) & laws.
o Biodiversity
o Conservation
Establishment of Department of Environment in Malaysia)
Government approved the Environmental Quality Act as a law on 14 March 1974 and
enforced on 15 April 1975.

Division of Environment (BAS) was established on 15 September 1975 under the
Ministry of Local Government and Environment.

BAS was moved to Ministry of Science, Technology and Environment on March 1976.

BAS upgraded to Department of Environment (JAS) on 1 September 1983.

JAS was moved to the Ministry of Natural Resources and Environment on April 2006.
 World Commission on Environment and
Author
Development
Subject Sustainability
Publisher Oxford University Press
Publication
1987
date
Pages 383

ISBN 019282080X

Our Common Future, also known as the Brundtland Report, from the United Nations World
Commission on Environment and Development (WCED) was published in 1987.

Its targets were multilateralism and interdependence of nations in the search for a sustainable
development path. The report sought to recapture the spirit of the Stockholm Conference - which
had introduced environmental concerns to the formal political development sphere. Our Common
Future placed environmental issues firmly on the political agenda; it aimed to discuss the
environment and development as one single issue.

The document was the culmination of a “900-day” international-exercise which catalogued,
analysed, and synthesised: written submissions and expert testimony from “senior government
representatives, scientists and experts, research institutes, industrialists, representatives of non-
governmental organizations, and the general public” held at public hearings throughout the
world.
The Brundtland Commission's mandate was to:

1. “ re-examine the critical issues of environment and development and to formulate
innovative, concrete, and realistic action proposals to deal with them;
2. strengthen international cooperation on environment and development and to assess and
propose new forms of cooperation that can break out of existing patterns and influence
policies and events in the direction of needed change; and
3. raise the level of understanding and commitment to action on the part of individuals,
voluntary organizations, businesses, institutes, and governments” (1987: 347). “The
Commission focused its attention in the areas of population, food security, the loss of
species and genetic resources, energy, industry, and human settlements - realizing that all
of these are connected and cannot be treated in isolation one from another”

The Brundtland Commission Report recognised that human resource development in the form of
poverty reduction, gender equity, and wealth redistribution was crucial to formulating strategies
for environmental conservation, and it also recognised that environmental-limits to economic
growth in industrialised and industrialising societies existed. The Brundtland Report claimed that
poverty reduces sustainability and accelerates environmental pressures – creating a need for the
balancing between economy and ecology. As such, the Report offered “[the] analysis, the broad
remedies, and the recommendations for a sustainable course of development” within such
societies (1987: 16). However, the Report was unable to identify the mode(s) of production that
are responsible for degradation of the environment, and in the absence of analysing the principles
governing market-led economic growth, the Report postulated that such growth could be
reformed (and expanded); this lack of analysis resulted in an obfuscated-introduction of the term
sustainable development.

The publication of Our Common Future and the work of the World Commission on Environment
and Development laid the groundwork for the convening of the 1992 Earth Summit and the
adoption of Agenda 21, the Rio Declaration and to the establishment of the Commission on
Sustainable Development.

An oft-quoted definition of sustainable development is defined in the report as:

"development that meets the needs of the present without compromising the ability of
future generations to meet their own needs."

In addition, key contributions of Our Common Future to the concept of sustainable development
include the recognition that the many crises facing the planet are interlocking crises that are
elements of a single crisis of the whole and of the vital need for the active participation of all
sectors of society in consultation and decisions relating to sustainable development.

Our Common Future is also known as the Brundtland Report in recognition of former
Norwegian Prime Minister Gro Harlem Brundtland's role as Chair of the World Commission on
Environment and Development.

(Source: Wikipedia)
UN Conference on the Human Environment
The United Nations Conference on the Human Environment was held in Stockholm, Sweden
from June 5–16 in 1972.

When the UN General Assembly decided to convene the 1972 Stockholm Conference, at the
initiative of the Government of Sweden to host it, UN Secretary-General U Thant invited
Maurice Strong to lead it as Secretary-General of the Conference, as the Canadian diplomat
(under Pierre Trudeau) had initiated and already worked for over two years on the project.

History
Sweden first suggested to the United Nations Economic and Social Council ECOSOC in 1968
the idea of having a UN conference to focus on human interactions with the environment.
ECOSOC passed resolution 1346 supporting the idea. General Assembly Resolution 2398 in
1969 decided to convene a conference in 1972 and mandated a set of reports from the UN
secretary-general suggesting that the conference focus on "stimulating and providing guidelines
for action by national government and international organizations" facing environmental issues.

Stockholm Declaration
The meeting agreed upon a Declaration containing 26 principles concerning the environment and
development; an Action Plan with 109 recommendations, and a Resolution. Principles of the
Stockholm Declaration:
1. Human rights must be asserted, apartheid and colonialism condemned
2. Natural resources must be safeguarded
3. The Earth's capacity to produce renewable resources must be maintained
4. Wildlife must be safeguarded
5. Non-renewable resources must be shared and not exhausted
6. Pollution must not exceed the environment's capacity to clean itself
7. Damaging oceanic pollution must be prevented
8. Development is needed to improve the environment
9. Developing countries therefore need assistance
10. Developing countries need reasonable prices for exports to carry out environmental
management
11. Environment policy must not hamper development
12. Developing countries need money to develop environmental safeguards
13. Integrated development planning is needed
14. Rational planning should resolve conflicts between environment and development
15. Human settlements must be planned to eliminate environmental problems
16. Governments should plan their own appropriate population policies
17. National institutions must plan development of states' natural resources
18. Science and technology must be used to improve the environment
19. Environmental education is essential
20. Environmental research must be promoted, particularly in developing countries
21. States may exploit their resources as they wish but must not endanger others
22. Compensation is due to states thus endangered
23. Each nation must establish its own standards
24. There must be cooperation on international issues
25. International organizations should help to improve the environment
26. Weapons of mass destruction must be eliminated

One of the seminal issues that emerged from the conference is the recognition for poverty
alleviation for protecting the environment. The Indian Prime Minister Indira Gandhi in her
seminal speech in the conference brought forward the connection between ecological
management and poverty alleviation.

Some argue that this conference, and more importantly the scientific conferences preceding it,
had a real impact on the environmental policies of the European Community (that later became
the European Union). For example, in 1973, the EU created the Environmental and Consumer
Protection Directorate, and composed the first Environmental Action Program. Such increased
interest and research collaboration arguably paved the way for further understanding of global
warming, which has led to such agreements as the Kyoto Protocol and the Paris Agreement, and
has given a foundation of modern environmentalism.

(Source: Wikipedia)
Water in the Environment

1
> Water Usage 2
 Water Properties
Unique physical & chemical properties make
water suitable or “fit” for the support of life
as we know it.
Water plays so many & such important roles
in the functioning of the Biosphere.
Water is in unique abundance on our planet.
The only material that exists in all three
physical states at the earth’s surface ie.
liquid, solid, and gas.

> Water 3
 DENSITY of H²O reaches a max at 277K (unlike
that of most other liquids)
NB. A no. of important ecological & env.
Consequences may be attributed to the
expansion of H²O as it freezes
eg¹. the intiation of rock weathering by ice formation in small
cracks & fissures (crystal of ice expand & enlarge cracks).
Water expands when freezing.
eg². Thermal stratification of lakes.
The unusually low density of ice & of liquid water just above
the melting pts. Is attributed to the open structure of water
molecule.

> Density 4
SURFACE TENSION
Water has high surface tension.
water molecules’ ability to form large no. of
strong hydrogen bonds=>large surf tension.
eg. Many insects able to walk on the surfaces
of lakes& streams
eg. Capillarity movement of awater in plant
vessels & retention of it in bet. soil particles.
The combination of tension & adhesion
produces force that enhance circulation of
water in plants, soils, and blood streams of the
body.

> Surface Tension 5
> A water strider on water surface 6
THERMAL PROPERTIES
Water has large heat capacity (75.5 J/mol
K) allows a given qty of heat to be
stored with minimal temp change, & its
large thermal conductivity allows for
rapid transfer of heat to or from
adjacent substances.
eg. Organisms (eg man) require a narrow range of
temp for their internal env have used this for
excellent thermoregulation systems.
eg. Entire Biosphere moderated by storage of solar
energy in water or its phase changes.

> High thermal capacity 7
LIQUID FORM
Pure water is colorless, odorless, &
transparent. These properties are
necessary for maximum benefits, such
as plant growth. For example, the
transparency of water permits light
penetration in streams & lakes so vital
in sustenance for aqueous animals &
plants.
eg. photosynthesis

> Colorless, odorless & transparent 8
Example: Thermal stratification of a lake.
Lake stratification - separation of lakes into 3 layers:
Epilimnion (top of the lake); Metalimnion or thermocline
(middle layer); Hypolimnion (the bottom layer).

> Water and thermal stratification 9
Example: Thermal stratification of a lake (Refer Fig.)
If water behaved as most liquids, lakes would freeze
solid in winter (where temp drops below 273K for
extended periods). Fish & aquatic organisms would
die due to water being frozen. Instead, a layer of
water at 277K collects at the bottom of lakes while
only the surf layer freezes.
In summer the opposite situation: a layer of water
warmed by solar radiation collects at the surf
above colder, denser liquid at the bottom.
In spring & fall, as the surf layer warms & cools, a
point is reached at which the entire lake is nearly
uniform in temp so that vertical mixing (turnover)
can occur. This distributes dioxygen & nutrients
throughout the water.

> Water and thermal stratification 10
> Water and thermal stratification 11
 Majority aquatic organisms are cold-blooded ie.
They have v little control over their body temp.
High heat capacity of water helps: a body of
water able to gain or lose relatively large qty of
heat without suffering correspondingly large
changes in temp. Because of this, the organisms
do not have the problem of their own body temp
changing all the time.
A gram calorie (cal.) is the amt of heat energy
required to raise the temp of one gram of water
from 14.5 oC to 15.5 oC. One kilocalorie (kcal. Or
Cal.) is equal to 1,000 gram calories. Food
Calories for human diets are usually measured in
kilocalorie.

> High thermal capacity of water 12
VISCOSITY
Water has very low viscosity.
This mobility allows easy
transportation, as well as use as an
avenue for movement of boats & ships.
The buoyancy of the fluid enhances its
effectiveness as a medium for
transportation.

> Viscosity 13
 The Water Cycle
When rainwater falls on land, some evaporates
again into atmosphere, some is absorbed by
plants or drunk by animals, some runs off the surf
of land into streams and lakes, some percolates.
The endless cycling of water maintains the various
freshwater environments & supplies the vast
quantities of water necessary for life on
land/earth. Water is a renewable resource because
of the hydrologic cycle.
The water cycle is likewise a major factor in
modifying temperatures, & it provides for the
transport of chemical nutrients thru ecosystems.

> Roles of water cycle 14
> Hydrological Cycle 15
 Undesirable pollutants may be transported thru
water cycle. Eg. sulphur (H2SO4) of acid rain in
the atmosphere, toxic metals (Hg, As) &
pesticides (DDT).
These pollutants create env problems & some
may be harmful to organisms & man.

> Transportation of pollutants 16
> Water and acid rain 17
Water in the Environment

1
 WATER
Unique physical & chemical properties
Suitable or “fit” the support of the life as
we know it.
Plays so many & such important roles in
the functioning of the Biosphere.

2
 DENSITY of H²O reaches a max at 277K
(unlike that of most other liquids)
NB. A no. of important ecological & env.
Consequences may be attributed to the
expansion of H²O as it freezes
eg¹. Intiation of rock weathering by ice formation in
small cracks & fissures.
eg². Thermal stratification of lakes.
The unusually low density of ice & of liquid water just
above the melting pts. Is attributed to the open
structure of water molecule.

3
SURFACE TENSION
water molecule from large no.5 of
strong hydrogen bonds=>large surf
tension.
eg. Many insects able to walk on the
surfaces of lakes& streams
eg. Capillarity movement of awater
in plant vessels & retention of it in
bet. soil particles.

4
5
Water Cycle
6
Water and acid rain
7
Atmospheric Science
& Pollution

1
 What is air pollution ?

Air pollution may be defined as the
presence in the air (outdoor atmosphere) of
one or more contaminants or combinations
thereof in such quantities and of such
durations as may be or tend to be injurious
to human, animal or plant life, or
property, or which unreasonably
interferes with the comfortable
enjoyment of life or property or conduct
of business.
2
 Primary pollutants
– Emitted directly into the environment
e.g. CO, NOx and HC from motor
vehicle exhaust
Secondary pollutants
– Formed by reaction in the environment
E.g. O3 and PAN formed in
photochemical smog from reaction of
above primary pollutants

3
 Major
Pollutants

Pollutants

Minor Secondary
Pollutants Pollutants

Pollutants 4
 Sulfur oxides (SOx) especially sulfur dioxide are emitted
from burning of coal and oil.
Nitrogen oxides (NOx) especially nitrogen dioxide are
emitted from high temperature combustion. Can be seen
as the brown haze dome above or plume downwind of
cities.
Carbon monoxide is colourless, odourless, non-irritating
but very poisonous gas. It is a product by incomplete
combustion of fuel such as natural gas, coal or wood.
Vehicular exhaust is a major source of carbon monoxide.
Carbon dioxide (CO2), a greenhouse gas emitted from
combustion.

5
 Volatile organic compounds (VOC), such as
hydrocarbon fuel vapors and solvents.
Particulate matter (PM), measured as smoke and dust.
PM10 is the fraction of suspended particles 10
micrometers in diameter and smaller that will enter the
nasal cavity. PM2.5 has a maximum particle size of 2.5
µm and will enter the bronchies and lungs.
Toxic metals, such as lead, cadmium and copper.
Chlorofluorocarbons (CFCs), harmful to the ozone
layer emitted from products currently banned from use.

6
 Ammonia (NH3) emitted from agricultural
processes.
Odors, such as from garbage, sewage, and
industrial processes
Radioactive pollutants produced by nuclear
explosions and war explosives, and natural
processes such as radon.
Peroxyacetyl nitrate (PAN) similarly formed from
NOx and VOCs.

7
 Local
– e.g. heat island
Regional
– e.g. acid rain
Global
– e.g. depletion of ozone layer, global warming

Major environmental issues related to
> atmosphere 8
 An urban heat island (UHI) is a
metropolitan area which is significantly
warmer than its surrounding rural areas.
The temperature difference usually is
larger at night than during the day and
larger in winter than in summer, and is
most apparent when winds are weak.

> What is heat island ? 9
> Urban heat island profile 10
>
>
Thermal Inversion
(from heat island)

13
Temperature inversion
14
 In the presence of a temperature inversion, the air near
the surface is trapped and cannot move upward. In this
case gases emitted at the surface do not dilute, and the
concentration of pollutants increases.
Temperature inversions happen in cities that are in valleys
such as Denver and Mexico City. In this case the inversion
happens because of radiative cooling from the surface.
At night the surface cools by emission of infrared
radiation, so that the coldest air is adjacent to the Earth’s
surface and the air temperature increases with altitude.
This inversion generally persists until the surface is
warmed again the next morning by absorption of
sunlight.
Thermal inversions are also common in areas near
mountain ranges such as in southern California. In this
case, the temperature increases because of air that
warms up as it descends down the mountain slope.

> 15
Inversion Layer
16
> The changes 17
 Heat islands form as cities replace natural
land cover with pavement, buildings, and
other infrastructure. These changes
contribute to higher urban temperatures in
a number of ways:
– Displacing trees and vegetation minimizes the natural
cooling effects of shading and evaporation of water from
soil and leaves (evapotranspiration).
– Tall buildings and narrow streets can heat air trapped
between them and reduce air flow.
– Waste heat from vehicles, factories, and air conditioners
may add warmth to their surroundings, further
exacerbating the heat island effect.

> What is heat island ? 18
Displacing trees and vegetation minimizes the natural cooling
effects of shading and evaporation of water from soil and
leaves (evapotranspiration). 19
Urban heat island profile 20
 Tall buildings and narrow streets can heat air trapped between
them and reduce air flow.

Heat island in urban area 21
 Waste heat from vehicles, factories, and air conditioners
may add warmth to their surroundings, further
exacerbating the heat island effect.

> Emission 22
 Wearing out (reduction) of the amount of
ozone in the stratosphere.

> What is depletion of ozone layer? 23
24
25
26
 Exposure to ambient ozone, even at low levels,
may trigger a variety of health problems,
especially in vulnerable populations such as
children, the elderly, and those with pre-existing
respiratory disease.
Because wind can carry ozone and its precursors
hundreds of miles, even residents far away from
urban centers and sources of pollution can be at
risk. There are specific health effects associated
with ozone exposure. The specific health effects
include:

> Health Effects Associated with Ozone Exposure 27
 Ozone can irritate lung airways and cause
inflammation;
Repeated exposure to ozone pollution for
several months may cause permanent
lung damage;
Even low-level exposure can result in
aggravated asthma, reduced lung
capacity, and increased susceptibility to
respiratory illnesses; and
Studies have linked hospital admissions
and emergency room visits to ground-
level ozone exposure.

> 28
> Do you want to be like this ? 29
 Summary
Chemicals in the atmosphere that deplete
the Ozone layer are CFCs and related
compounds in the atmosphere i.e.
Chlorofluorocarbons (CFCs) and other
halogenated ozone depleting substances (ODS)
are mainly responsible for man-made chemical
ozone depletion.

CFCs were used in air conditioning and cooling
units, as aerosol spray propellants prior to the
1970s, and in the cleaning processes of delicate
electronic equipment.

> Effects of depletion of ozone layer 30
 Summary
Consequences of ozone layer depletion:
Increased UV
Biological effects
(i) Basal and squamous cell carcinomas.
The most common forms of skin cancer in
humans, basal and squamous cell carcinomas,
have been strongly linked to UVB exposure.

(ii) Malignant melanoma. Another form of skin
cancer, malignant melanoma, is much less
common but far more dangerous, being lethal in
about 15–20 percent of the cases diagnosed.

> Effects of depletion of ozone layer 31
(iii) Cortical cataracts. Epidemiological studies
suggest an association between ocular cortical
cataracts and UVB exposure.

(iv) Increased tropospheric ozone. Increased
surface UV leads to increased tropospheric
ozone. Ground-level ozone is generally
recognized to be a health risk, as ozone is toxic
due to its strong oxidant properties.

(v) Increased production of vitamin D.
Vitamin D is produced in the skin by ultraviolet
light. Thus, higher UVB exposure raises human
vitamin D in those deficient in it.

> 32
(vi) Effects on animals. A November 2010 report
by scientists at the Institute of Zoology in London
found that whales off the coast of California have
shown a sharp rise in sun damage. The findings
suggest "rising UV levels as a result of ozone
depletion are to blame for the observed skin
damage, in the same way that human skin cancer
rates have been on the increase in recent decades.

(vii) Effects on crops. An increase of UV radiation
would be expected to affect crops. A number of…

> 33
……economically important species of plants, such
as rice, depend on cyanobacteria residing on their
roots for the retention of nitrogen. Cyanobacteria
are sensitive to UV radiation and would be affected
by its increase. "Despite mechanisms to reduce or
repair the effects of increased ultraviolet radiation,
plants have a limited ability to adapt to increased
levels of UVB, therefore plant growth can be
directly affected by UVB radiation.

(Source: Wikipedia)

> 34
 Acid rain is rain or any other form of
precipitation that is unusually acidic. It
has harmful effects on the environment
and on structures.

It is mostly caused by emissions due to
human activity of sulfur and nitrogen
compounds which react in the atmosphere
to produce acids. In recent years, many
governments have introduced laws to
reduce these emissions.

> Acid Rain 35
 Natural Phenomena
– The principal natural phenomena that contribute acid-
producing gases to the atmosphere are emissions from
volcanoes and those from biological processes that occur
on the land, in wetlands, and in the oceans. The major
biological source of sulfur containing compounds is
dimethyl sulfide.
– The effects of acidic deposits have been detected in
glacial ice thousands of years old in remote parts of the
globe.

> 36
 Human activity
– The coal-fired
– The principal cause of acid rain is sulfur and nitrogen
compounds from human sources, such as electricity
generation, factories and motor vehicles. Coal power
plants are one of the most polluting.

> 37
CO2 Emission -
countries

38
Global CO2 - What is our action ? 39
Acid rain
formation

40
 Acid rain was first found in Manchester,
England. In 1852, Robert Angus Smith
found the relationship between acid rain
and atmospheric pollution. Though acid
rain was discovered in 1852, it wasn't until
the late 1960s that scientists began widely
observing and studying the phenomenon.
Canadian Harold Harvey was among the
first to research a "dead" lake.

> History of Acid Rain 41
 normal rainwater
has a pH of about
5.7 (Coates, 1981).
lowers the pH of soil,
killing soil
organisms, leaching
nutrients from soil,
decreasing soil’s
ability to support
crops

> pH 42
 Surface runoff of acid rain lowers the pH of
streams and lakes, threatening valuable
ecosystems.
If pH drops below 5.0, fish usually disappear
completely and plant life is drastically altered.
Fish eggs extremely sensitive to slight drops in
pH.
Induce the corrosion of solids. Damage to
sculptures, cathedrals, and other stone or metal
structures.
A common chemical reactions combines sulphuric
acid in rain with limestone or marble (CaCO3):

> Effects of acid rain 43
 CaCO3 + H2SO4 + H2O → CaSO4.2H2O
+ CO2 
Corrosion of limestone by acid, produces
gypsum. Tiny amts of gyp crystallize in
small interstices of stone as it drys out.
Thus, accelerates nat. weathering
(pressures exerted by growing crystals
cause cracks in rock).

> 44
> Effects of acid rain to environment 45
> 46
Why people are keep talking
about Global Warming ?

> Global Warming 47
> Is it real ? 48
> Or you just want to wait ? 49
> Do you ? 50
> Global warming “melting” the earth ? 51
> Everybody experience global warming ? 52
> “Everyone” enjoy the global warming ? 53
> Even Malaysia experience the global warming
54
> Global Warming – Local perspective 55
 An increase in the average temperature of
the Earth
Recent debate, but has been looked at by
scientists for centuries

> So what is GLOBAL WARMING ? 56
> Changes in global temperature 57
 Future

Now

> How about in the future ? 58
> Greenhouse phenomenon 59
> 60
Human Impacts:
Greenhouse Gases:

CO2
Methane
Nitrous oxide
Fluorinated
compounds

> What causes it? 61
 Natural Impacts
– Volcanoes
– Water Vapor
– Cloud

> What causes it? 62
 Burning of fossil fuels is main cause
US is leader in greenhouse gasses
Human impacts are changing the
composition of the atmosphere

> Who’s Responsible? 63
> Greenhouse gasses 64
Ice melting

65
Land-based glaciers are retreating nearly everywhere
around Earth: Triftgletscher Glacier, Switzerland. Since the
1850s ice cover in European alpine regions has decreased
From 4,472 km2 to 2,272 km2.
Photos: Michael Hambrey; Data: World Glacier Monitoring Service 2006

66
Observed changes in global
climate parameters since
1970, (solid lines), compared
to IPCC projections (broken
lines with grey ranges):

(a) Atmospheric CO2
concentration

(b) Annual global mean
surface temperature (land
+ oceans)

(c) Sea level data from tide
gauges (red line) and satellite
altimeters (blue line)

From: Rahmstorf et al. 2006 67
> 68
> 69
 Rising sea level
1

Changes of precipitation pattern, local climate and acid
2 rain

Expansions of desert
3

More Intense rainstorms
4

Not all long term effects can be determined
5

Effects of Air Pollution and Global Warming 70
 What Is Being Done:
Alternatives
Renewable Energy Sources

Solar Energies
Wind Power
Biomass
Geothermal

71
 Changes In Vehicle Systems

Hybrid

Fuel Cell

Battery-Electric

72
73
 Responsibility to improve environmental conditions
lies upon all of us as individuals
Concentrate on preventing environmental
degradation before it starts

> What you have to do ? 74
> 75
 References

Johnson, R. & Morrell, P. (1982).
Environmental Science. Blackie & Son,
London.

> What you have to do ? 76
 The Atmosphere
1. Atmosphere’s Structure.
 There is considerable variation of temperature with height which forms the basis for the
classification of the atmosphere into layers.
 Temperature Profile – controlled mainly by degree of absorption of solar radiation in the
various region.
 Ozone contributes to the warming of the stratosphere.
 Another source of heat is absorption of visible radiation by the earth’s surface and by
clouds in the lower troposphere, that leads to the profile of decreasing temp with height
observed up to an altitude of 10 km.

 Temp profile – importance in determining the stability and degree of mixing of the
atmosphere as a whole as well as those small parts of it in contact with cities or other
high pollution areas.
 Because its density is smaller, warm air rises above cold at the same pressure. In the
atmosph., however pressure decreases significantly with altitude, allowing rising warm
air to expand. Because air is poor conductor of heat its expansion is usually adiabatic
and its temp must decrease by an amount equivalent to the work it does by expanding.
If the rising air cools sufficiently, it will reach the same temp and density as its
 surroundings and its rise will therefore halted. If the temp profile of the surroundings is
such that at higher altitudes they are cooler than the rising body of air, the latter can
continue upward.

 In the troposphere much water vapour is present which can condense and release heat
as rising air expands. This reduces the cooling effect.
 Although vertical mixing may be absent at specific times and places, the general
behavior of the troposphere is such that pollutants will be dispersed and diluted. On the
other hand, the stratosphere exhibits stable atmospheric behavior. Because its temp-
altitude profile has a positive slope vertical mixing is very slow. Material injected into
the stratosphere tends to remain at a given altitude for years, eventhough it may be
carried many times around the globe by jet-stream winds. A good example, a thin band
of(NH4)2SO4 aerosol which has been discovered at an altitude of 20 km.

[Source: Environmental Chemistry, JW Moore & EA Moore, 1976].
2. Temperatute Inversion and Air Pollution.

 Lapse rate, defined as the change in temp with increasing altitude.
 A temp-altitude profile: When the lapse rate is positive and temp increases with
altitude, even for only a short distance, a temperature inversion is said to exist.
 Stable atmospheric conditions prevent vertical motion within the inversion layer; thus,
gases and suspended matter become trapped and cannot rise past the altitude at which
temp begins to increase. If an inversion occurs above a city or industrial region,
pollutants which normally disperse throughout the troposphere cannot do so. This is
important in a valley or among skyscrapers in a city where horizontal transport of
hazardous substances is also cut off.