AECC Unit 2 Natural Resources PDF

Summary

This document discusses natural resources, including land, forest, water, food, and energy resources. It covers definitions, types, and classifications of natural resources. The document also explores land resources, soil composition, and the significance of land in supporting ecosystems.

Full Transcript

Natural Resources
We will discuss and learn in this unit about:
Natural resources: definition, concept and types
Land resources
Forest resources
Water resources
Food resources
Energy resources
❖ Syllabus of this Unit as per CD is:

Natural resources: Land resources and land use change, land degradation,
soil erosion and desertification.

Deforestation: causes and impacts due to mining, dam building on
environment, forests, biodiversity and tribal population.

Water Resources: Use and over-exploitation of surface and groundwater,
floods, drought, conflicts over water (international and inter-state).

Heating of earth and circulation of air; air mass formation and precipitation.

Energy resources- renewable and non-renewable energy sources, use of
alternate energy sources, Growing energy needs, Case studies.
 Life on the earth depends upon a large number of things and services which are
provided by nature and are, thus, known as Natural Resources.
Water,
Air,
Soil,
Minerals,
Coal,
Forests,
Crops and
Wildlife.
Natural resources vary in their nature, origin, availability, exhaustibility, extent,
etc. Some natural resources, like air, solar energy, etc. are inexhaustible and thus
can be used unlimitedly while as others exhaustible resources get consumed on
being used and require judicious utilization.
 Renewable resources have the capability to renew themselves if used within
certain limits.
All natural resources, however, demand a proper and clever use.
Reckless and injudicious utilization of natural resources is bound to lead
us to an era full of all sorts of crises.
Reckless use not only leads to the acute shortage of resources but may also
result in generation of unmanageable wastes and contamination of our
environment which is a storehouse of all the resources.
There must be sustainable use of natural resources in order to safeguard
our own persistent survival.
3.1. Introduction:
Any material which is naturally available and can be used or transformed to be used
in any way by man for his well being is called a Natural Resource.
Thus a natural resource is anything that we can use and which comes from nature.
Air, water, sun, wood, oil, iron, and coal etc are all examples of natural resources.
Natural resources, thus, must:
Be naturally occurring on the earth.
Useful to man in any way that is either directly in its original form or indirectly after
certain modification.
Accessible to man. If something very useful to man is known to occur somewhere but
is out of human reach or we do not have appropriate tools and technology to extract
or use it, it is not a natural resource for us.
Modifiable or convertible to more useful products. It means we should have
appropriate technology to make use of a natural resource.
 Refined oil and hydro-electric energy are not natural resources because people
make them.
The earth is seemingly an inexhaustible storehouse of innumerable natural
resources.
Although there are vast treasures of different resources on the earth, they are
not unlimited or inexhaustible. Some resources are renewable while others are
not. Man has been exploiting major groups of resources including land, fossil
fuels, forests, wildlife, etc.
Which have now been depleted to an irreparable extent. We need to switch over
to alternative and nonconventional resources in order to avoid problems
associated with scarcity of resources.
3.2. Classification of Natural Resources:
There are numerous natural resources required and utilized by man in his day-to-day life.
There are various basis of classifying natural resources into various groups.
These bases include
✓ On the basis of origin
Biotic such as forest, coal, food, etc
Abiotic such as water, air, land, minerals, etc
✓ On the basis of nature
Organic such as coal, oil, etc
Inorganic such as coal, mica, gold, etc
✓ On the basis of renewability
Renewable such as forest
Non-renewable such as coal
 ✓ On the basis of exhaustibility
Exhaustible such silver, gold, forest, oil, coal, etc
Inexhaustible such as wind, solar energy, etc
✓ On the basis of tradition/convention
Conventional such as oil, coal, etc.
Non-conventional such as wind, tidal energy, solar energy, etc.

We often hear there are two kinds of natural resources:
Renewable resources and Non-renewable resources.

✓ A renewable resource grows again and comes back again after we use it.
For example, soil, sunlight, water and wood are renewable resources.
✓ A non-renewable resource is a resource that does not grow and come back,
or a resource that would take a very long time to come back.
For example, coal is a non-renewable resource. When we use coal, there
is less coal afterward. One day, there will be no more of it to make goods.
The non-renewable resource can be used directly (for example, burning
oil to cook), or we can find a renewable resource to use (for example,
using wind energy to make electricity).
 Most natural resources are limited. This means they will eventually run out.
A perpetual or endless resource has a never-ending supply. Some examples of
perpetual resources include solar energy, tidal energy, and wind energy.
It is very important to protect and conserve our natural resources and use them in
a judicious manner so that we do not exhaust them.
It does not mean that we should stop using most of the natural resources. Rather,
we should use the resources in such a way that we always save enough of them
for our future generations.

In the coming slides we ‘ll discuss some important natural resources such as
forest resources, water resources, food resources, energy resources and land
resources in detail
3.3. Land Resources:
Land in general refers to any piece or entire of the terrestrial earth but as a
natural resource it means that component of the earth which is of direct economic
use for the human population living on it.
In fact land is one of the most important natural resources upon which we depend
for our
food,
fibre and
fuel wood, the basic amenities of life.
But this resource is not infinite. There are limited land resources available for direct
human use.
It is the top soil or the uppermost portion of the earth crust that actually forms
useful land resource.
 Land is classified as a renewable natural resource because it is continuously
regenerated by natural process though at a very slow rate.
But, when rate of erosion is faster than rate of renewal, the soil becomes a non-
renewable resource.
It is said that about 200-1000 years are needed for the formation of one inch of
soil.
Following are some important factors which affect or decide the value of land as a
significant natural resource:

Soil and terrain conditions ✓ Thus, natural resources, in the context
Freshwater conditions of “land”, are taken to be those
components of land units that are of
Climatic conditions, and direct economic use for human
Biotic(vegetation and animal life) population living in the area, or
conditions expected to move into the area.
The basic functions of land in supporting human and other terrestrial ecosystems
are:
Land is a store of wealth in its own.
Land is a storehouse of minerals and raw materials for human use.
Land helps in the production of food, fibre, fuel, etc.
Land is the biological habitat for many plants, animals and microorganisms.
Land regulates flow of surface water and stores groundwater.
Land enables or hampers movement of people and animals between one place to
another.
Land is a buffer, filter or modifier for chemical pollutants.
Land is co-determinant in the global energy balance and the global hydrological
cycle, which provides both a source and sink for greenhouse gases.
 Land is the physical space for settlements, industry and recreation.
Land stores and protects evidence of past climates, archaeological remains from
the historical or prehistorical record.
3.3.1. Texture, Structure and Composition of Soil:
Soil is an uncemented aggregate of mineral grains and decayed organic matter with
water and air occupying the void spaces between particles.
Soil Texture:
Soil texture refers to the size distribution of soil particles and the relative percentage
of sand, silt and clay in a soil.
Three sizes of particles are recognized in soil. These are tabulated below:
The relationship between particle size and class names is:

It is to be noted that a clay soil remains clay and a sandy soil remains sandy
because the size of particles in the soil is not subject to ready change.
 Soil texture controls the following properties of soil with respect to plant
growth:
aeration,
availability and movement of water,
content of plant nutrients, and
workability.

✓ For instance, movement of water in various soil-textured types is illustrated
Water drainage from various types of soils
Soil Structure:

Soil structure refers to the arrangement of soil particles into groups or aggregates.
The peds are natural, fairly water stable aggregates; and clods are artificial, water
unstable aggregates. Ploughing of wet clay soil makes the soil cloddy.
Soil structure is divided into the following groups:
(a) Types of soil structure.
Examples: Platy, spheroidal, etc
(b) Class of soil structure.
Examples: Fine, medium, coarse, etc.
(c) Grades of soil structure.
Examples: Weak, strong, etc.
Soil Composition:
✓ Four major components of soils are mineral materials, organic matter, water and air.
Approximate composition of soil is given below:

(i) Mineral Materials
(a) Mineral materials are elements (Si, Fe, O, Mg, Al, Ca, Na and K), finely
divided quartz (SiO2), iron-silicates and aluminium silicates.
(b) They are derived from the underlying bedrock or from materials
transported and deposited by surface run-off, wind fl ow, etc.
(c) Secondary minerals (viz., Na+, K+, Ca2+, Mg2+, H+, NH+4) are held at
the surface of all the silicate clays. These are not leached by water and
are exchanged. Thus, they are available as plant nutrients.
(ii) Organic Matter
(a) Organic matter can be crop residues, weeds, grasses, bacteria, fungi, other
microorganisms and animal manures.
(b) They come from the residues of plants and animals.
(c) Functions
They provide food for microorganisms, other nutrients to plants. Thus, soil
productivity is controlled by them.
They provide a storehouse for nutrients.
They increasing water holding capacity of soil.
(iii) Water
It is a good solvent for many nutrients which move into plant roots. Water is also
important to maintain the proper form and position of leaves and new shoots for
capturing sunlight and satisfactory growth.
(iv) Air
Soil air encourages optimum rate of the essential metabolic processes of various
organisms.
Land Resources
 Land is very basic requirement of man for various types of life-related activities.
As a valuable resource land is, used for:
building houses, constructing roads and railways, installing industries and
developing towns and cities on it.
cultivating food and fodder for humans and their livestock
production of raw materials for industries
raising forests and other industrial woodlands
damping of waste generated during domestic and industrial processes
In addition, we have to conserve wilderness area in forests, grasslands,
wetlands, mountains, coasts, etc. to protect our vitally valuable biodiversity.
This use of land is equally important.

It demands a rational use of land resources, and it can be achieved through careful
planning.
 Land use involves the management and modification of natural environment or
wilderness into built environment such as settlements and semi-natural habitats such as
arable fields, pastures, and managed woods.
Land use planning refers to policy of using a portion of land strictly for the purpose it
is suitable.
Different types of land are classified into various categories. Each category is assigned
a suitable type of use and it should be utilized for the purpose fixed for it.

3.3.2. Global Land Use Patterns:

Though the earth is a vast planet with huge surface area but 71% of it is under oceans.
The Earth’s total land area is 148,939,063.133 km².
Out of this terrestrial surface very limited land area is effectively useful or accessible
for man.
 A large proportion of it is either inaccessible or unfit for any cultivation or residential
uses.
About 15.46% of the land occurs in the cold tundra zone, which is not easily
amenable to normal agriculture.
Land which is capable of being ploughed and used to grow crops is called arable land.

Major categories of land include:
Urban or Built-up Land Degraded Land
Agricultural Land Tundra
Rangeland Perennial snow or ice
Forest Land
Wetland
Barren Land
Landform Types
According to Buringh (1989)
11 to 12 % of the land surface is generally suitable for food and fiber
production,
24 % is used for grazing,
forests occupy about 31 % and
the remaining 33 % has too many constraints for most uses.
Land is being put to varied types of uses worldwide.
With increase in human population and advancement in the technology, more and more
land had been brought under various types modifications.
Now more land is required to be used for agricultural purposes to meet the growing
needs of food production.
With his economic developmental activities gaining momentum, man put land to various
other uses including establishment of industrial areas, mining, transportation,
urbanization, etc. As a result:
 Agricultural lands are expanding
More and more land has been brought under industrial or urban setup
Forest lands, grasslands and wetlands has been cleared of their natural cover
Large portions of land are rendered degraded due to overexploitation
Soil is dumped with various kinds of wastes and toxic materials
3.3.3. Land Degradation:
Land degradation means reduction in the quality or value of land.
When land is put to extensive use or over exploitation its quality degrades.
Sometimes land is put to uses which are not suitable for that piece of land. It also
degrades the land.
Farmland is under serious threat due to more and more intense utilization. Every
year, between 5 to 7 million hectares of land worldwide is added to the existing
degraded farmland.
Some factors responsible for degradation of land include:

Dumping of harmful wastes on land
Over irrigation of farmland that leads to salinization
Pollution of land due to use of fertilizers and pesticides
Unsuitable land use
Soil erosion and landslides
Wrong agricultural practices
Deforestation
 Mechanisms that initiate land degradation include physical, chemical, and
biological processes.
✓ Physical processes:
Decline in soil structure leading to crusting, compaction, erosion, desertification,
anaerobism, environmental pollution, and unsustainable use of natural resources.
✓ Chemical processes:
Acidification, leaching, decrease in cation retention capacity, and fertility
depletion.
✓ Biological processes:
Reduction in total and biomass carbon, and decline in land biodiversity. Soil
structure is an important property that affects all three degradative processes.
Sustainable Land Management
Land Resource Management
3.3.4. Soil Erosion:
Soil erosion is the most common form of land degradation. It is the removal of
outer layer of soil. It is defined as the movement of soil components, especially
surface-litter and top soil from one place to another.
Besides causing pollution in water bodies, soil erosion badly affects soil fertility. It
is the top layer of soil that contains most nutrients and if most fertile. When this
layer gets eroded it results in the loss of fertility.
Almost one third of the world’s cropland is affected by soil erosion.
Soil erosion is a natural process but it gets accelerated due various human activities.
Deforestation, mining, overgrazing, cultivation, etc enhances the rate of soil
erosion.
Causes of soil erosion:
Various human activities like
mining,
deforestation,
farming,
overgrazing, etc are the major causes responsible for soil erosion.
Due to these processes the top soil is disturbed or rendered devoid of vegetation
cover. So the land is directly exposed to the action of various physical forces
facilitating erosion.
Overgrazing is responsible for 35% of the world’s soil erosion while 30% of the
serious soil erosion has been caused by deforestation. Unsustainable methods of
farming cause 28% of soil erosion.
Mechanism of soil erosion:
There are two main agents which cause soil erosion. These are water and wind.
Water erodes soil by washing its particles along with its flow.
Wind also detaches and removes the soil particles and causes their movement from one
place to another.
✓ Soil erosion caused by water is of following types:
Sheet erosion: when there is uniform removal of a thin layer of soil from a large
surface area, it is called sheet erosion. This is usually due to run-off water.
Rill erosion: When there is rainfall and rapidly running water produces finger
shaped grooves or rills over the area, it is called rill erosion.
Gully erosion: It is a more prominent type of soil erosion. When the rainfall is very
heavy, deeper cavities or gullies are formed on the ground.
Slip erosion: This occurs due to heavy rainfall on slopes of hills and mountains.
 Stream bank erosion: During the rainy season, when fast running streams take a
turn in some other direction, they cut the soil and make caves in the banks.
✓ Soil erosion caused by wind is of following three types:
Saltation: This occurs under the influence of direct pressure of stormy wind and
the soil particles of 1-1.5 mm diameter move up in vertical direction.
Suspension: Here soil particles of small size suspended in the air are kicked up
and taken away to distant places.
Surface creep: Here larger particles (5-10 mm diameter) creep over the soil
surface along with wind.
Preventing Soil Erosion
Preventing soil erosion requires political, economic and technical changes.
Political and economic changes need to address the possibility of incentives to
encourage farmers to manage their land sustainably.
✓ Aspects of technical changes in agriculture that could substantially contribute to the
prevention of soil erosion are:
Use of contour ploughing and wind breaks
Leaving unploughed grass strips between ploughed land
Making sure that there are always plants growing on the soil, and that the soil is
rich in humus (decaying plant and animal remains). This organic matter is the
“glue” that binds the soil particles together and plays an important part in the
prevention of erosion
Avoiding overgrazing and the over-use of crop lands
 Allowing indigenous plants to grow along the river banks instead of ploughing
and
planting crops right up to the water’s edge
Encouraging biological diversity by planting several different types of plants
together
Conservation of wetlands.
3.3.5. Land Slides:

Geologists use a variety of classification schemes to describe the causes of
landslides.
Because of wide variety of causes, no single scheme has yet been developed that
addresses or describes all types of landslides.
Even the terms assigned to types of landslides are undergoing standardization
among geological and scientific international agencies.
The major causes of landslides can be classified into two groups, namely external
and internal as illustrated below:
All the major causes of landslides point towards some or other form of human
activity and hence it is essential to be discreet about developmental activities in
areas prone to landslides.
3.3.6. Desertification:

Desertification is a form of land degradation occurring particularly, but
not exclusively, in semi-arid areas.
While there is a clear distinction between ‘soil’ and ‘land’ (the term land
refers to an ecosystem comprising land, landscape, terrain, vegetation,
water, climate), there is no clear distinction between the terms ‘land
degradation’ and ‘desertification’.
Desertification refers to land degradation in arid, semi-arid, and sub-
humid areas due to anthropogenic activities.
Causes of Desertification:
Natural causes of desertification:
✓ Decreased rainfall
✓ Increased temperature
✓ Lowering of water table
✓ Soil erosion
✓ Soil compaction
Human-aided desertification:
✓ Overgrazing
✓ Destruction of forest belts (Deforestation)
✓ Salinization
✓ Exhaustion of the soil by intensive cultivation without restoration of fertility
3.4. Forest Resources:
❖ He we will learn and understand about the significance of forest resources and the
major threats to it such as mining and dams.

Due to rapid urbanization, the area of forest is decreasing all over the world. The
protection of forest resources is essential for the survival of our species.
Below observe the various living and non-living components of a natural forest.

A. Types of Forest Resources:
Forests are broadly classified into three categories from the point of view of use as
a resource:
(i) Old-Growth or Ancient Forests:
These are uncut forests that have not been seriously disturbed by natural
disasters or human activities. As a result, they have attained great age, and
thereby exhibit unique ecological features.
Components of Forest
(ii) Second-Growth Forests:
They result from secondary ecological succession that takes place when forests
are cleared and then left undisturbed for long periods of time.
(iii) Plantations:
These are (large, artificially established) forests of commercially valuable
trees. These are created mostly by clearing old-growth or second-growth
forests.

Differentiation characteristics of forests
“Automated analysis of forest satellite imagery is not reliable for estimating
forest cover.”
Explanation:
The Forest Survey of India (FSI) reported in 2009 that Indian forests had grown by
almost 5% per year from the 1990s. They used automated analysis of forest satellite
imagery.
But, the above method cannot differentiate between native forests and exotic tree
plantations (such as rubber, teak, pine, eucalyptus trees). The plantation forest
covers have very limited value for biodiversity.
Monoculture plantations are expanding by nearly 6,000 to 18,000 square kilometres
per year in India.
If one subtracts plantations from total forest cover then India’s native forests have
actually declined at an alarming pace, from 0.8% to 3.5% per year from 2000–2005.
B. Functions of a Forest:

❖ Forests help in production of timber, regulation of stream flow, control of erosion,
recreation, provision of wildlife habitat, etc.

Beneficial functions of forests are the following:
(i) Influence on Climate
The crowns of the trees hold the moisture in because the force of the wind is
broken. It makes the forest cool in the summer and warm in the winter.
(ii) Control of Run-off
Leaves and branches of trees break the impact of rain, causing it to drip rather
than have a strong force. Rain is absorbed by the ground, reducing surface run-
off.
(iii) Flood Control
Forested watersheds help in avoiding extremes of water flow and so help in
flood prevention.
(iv) Wildlife Habitat Provision
Wildlife uses the products of trees and forests as food and shelter respectively.
(v) Prevention of Soil Erosion
Water moves slowly through forested soils and stays free of sediments.
(vi) Reduction of Wind Erosion
Trees are used as windbreaks and slow down the force of wind.
(vii) Removal of Pollutants
The roots of trees absorb soil and water pollutants. Sulphur dioxide is used for
metabolism of trees. Thus, forests aid in the cleansing of air, water and soil.
(viii) Noise Abatement
Trees act as a sound barrier.
(ix) Recycling of Nutrients
Forests help in nutrient recycling.
(x) Provisions for Healthy Survival of Local Communities and Mankind
Forests provide employment and income, aesthetic pleasure and spiritual solace.
They also provide food, fiber, honey, medicinal plants and minerals.

Environmental and commercial value of forests
Some Uses and Benefits
of Forests for Humans
3.4.1. Deforestation:

Deforestation refers to the loss of forest cover; land that is permanently
converted from forest to agricultural land, golf courses, cattle pasture, homes,
lakes, or desert.
The depletion of forest tree crown cover less than 90% is considered forest
degradation.
Logging most often falls under the category of forest degradation and thus is
not included in deforestation statistics. Therefore, forest degradation rates are
considerably higher than deforestation rates.
If the current rate of deforestation continues, the world’s forests will vanish
within the next 100 years—causing unknown effects on global climate and
eliminating the majority of plant and animal species on the planet.
A. Causes of Deforestation:
The causes of deforestation are very complex. A competitive global economy
drives the need for money in economically weak developing countries.
At the national level, governments sell timber to raise money for projects, to
pay international debt, or to develop industry.

✓ Population explosion
✓ Agriculture: shifting cultivation, overgrazing, cash-crop economy, etc.
✓ Commercial logging: cutting trees for sale as timber or pulp
✓ Poverty
✓ Mining
✓ Dams
✓ Infrastructure creation for logging
✓ Forest fires
✓ Acid rain
✓ Development projects and housing projects.
Major Causes of Deforestation
B. Ill effects of Deforestation:
Since many people are dependent on the world’s forests, deforestation will have
many social, economic and ecological effects.
✓ The major effects of deforestation on the environment are:
Ill Effects of deforestation
C. Environmental Impacts of Deforestation:
(i) Atmosphere
Less CO2 taken in, burned trees add even more CO2, which traps heat,
causes more evaporation, and this leads to more precipitation.
More sunlight reaches surface, less photosynthesis, increased risk of fire. This
is responsible for global warming, which in turn causes deforestation (a).
(ii) Hydrosphere
Run-off increases, turbidity increases. More sediment at mouth of rivers, more
flash floods.
Increase of water temperature near river banks results in less availability of
oxygen in water ways. This is responsible for degradation of aquatic habitat
(b) & (d).
(iii) Geosphere/Lithosphere
Increased erosion from water and wind, top soil carried away, loss of
minerals (C, N, etc.), soil depleted quicker, less wood for construction, fuel
and other products (b).
(iv) Biosphere
Loss of vegetation, change of food supply, decreased habitat, decrease in
number of species, decrease of diversity, decrease of pollinators and seed
dispersers, loss of human cultural diversity (c) & (d).
D. Solutions to the Problems of Deforestation
Deforestation is a serious problem, but humans can make a difference. An
individual as well as a society can practice green consumerism.
The following actions could serve as effective solutions to the problem of
deforestation.
Reduce the consumption of forest and related products.
Avoid harmful products by consumer boycotts, such as tropical rainforest
wood, old-growth wood from the tropical rainforest.
Boycott products of companies involved in deforestation.
Compel government and industry to make changes in the forest policies.
Individuals may communicate their uncertainty about the future of the world’s
forests to politicians, corporate executives and non-governmental organizations
through personal communication or in groups using petitions and rallies.
Environmental conservation may be given importance in school curricula.
E. The Measures Taken for Conserving Forest Wealth
Sustainable Forest Management (SFM): SFM is the use of the world’s
forests in such a way that they continue to provide resources in the present,
without depriving future generations of their use.
Forest Certification: Be responsible consumers. Buy wood only from
companies that follow sustainable practices.
Involve Local Communities in Joint Forest Management (JFM): As
local communities want to continue to get the benefits they previously
enjoyed, they provide labour and help in conserving biodiversity. The
Government should provide them extractive reserves. These are protected
forests in which local communities are allowed to harvest fruits, nuts,
medicines, fibres, rubber, etc., in ways that do not harm the forest.
 Improve Governance and Accountability: The Government must take bold
political decisions and develop new civil society institutions to improve
governance and accountability regarding forest use. Stop harmful subsidies to
timber companies.
Accelerate Education, Research and Training: This is to ensure that SFM
and JFM can quickly become a reality.

❖ In 1988, the Government of India introduced a new forest policy that called for
significant change in the management of forest land.
❖ The draft National Forest Policy 2016 continues with the national goal of
maintaining a minimum of one-third of the geographical area under forest or tree
cover.
Types of Timber Extraction
Case Studies:
(i) Chipko Movement
‘ Chipko’ in Hindi means hugging or embracing. Contractors used to make huge
profi ts, from the feeling of trees in the hills. The Chipko movement was the hill
communities’ response to the unfair and destructive nature of this contract system. The
Chipko movement spread through India during the 1970’s.
As per the folk-poet Ghansyam Returi, Chipko movement is “Embrace the trees
in the forests and save them from being felled! Save the treasure of the mountains from
being looted away from us!”
The slogan of the Chipko movement was “What do the forests bear? Soil, water,
and pure air!”
The Chipko movement ensured that the contract system was abolished and the
indiscriminate felling of trees stopped. The Forest Development Corporation (FDC)
department was formed which works for the welfare of hilly areas and the people living
there. It enlightened the people about the necessity of ecological balance in the nature.
 The Chipko movement took place under the leadership of Sunder Lal Bahuguna
(an environmentalist and journalist) and Chandi Prasad Bhatt in Tehri Garhwal
(Uttarakhand). Sunderlal along with his wife, Vimla, has given his time and talent freely
to work for the good of India. He has been the catalyst of change, encouraging
thousands of people to work without pay for the good of India’s people and ecology,
through non-violent resistance. As a Gandhian peace worker, they do not resort to
violence to achieve the change.
Chandi Prasad Bhatt encouraged the development of local industries based on
the conservation and sustainable use of forest weather for local benefit. Forests in
Uttarakhand district covered more than 81% of its geographical area in 1950. The
Government initiated the process of development by allowing a pulp and paper mill, a
plywood factory and a chain of hydroelectric dams on rivers. Over-exploitation of forest
resources by these industries and submergence of huge forests and agricultural areas by
dams resulted in shrinking of the forests to nearly 25% of the district’s area by 1980.
The poor, local population was forced to displace. The conversion of the natural mixed
forests into eucalyptus and teak plantations dried up the water resources, directly
affecting forest dwellers, and resulted in poverty instead of intended development.
 The Chipko protests in Uttar Pradesh achieved a major victory in 1980 with a 15-
year ban on green felling in the Himalayan forests of UP by the order of the then Prime
Minister of India (Mrs Indira Gandhi). Since then, the movement has spread to many
states in India. The movement has also helped in stopping deforestation in the Western
Ghats and the Vindhyas.
(ii) The Bishnois
Jambhoji, a resident of a village near Jodhpur, Rajasthan had a vision in the
fifteenth century that the people’s interference with nature like felling of trees, killing of
animals would result in drought. Thereafter, he become a sanyasi and initiated the Bishnoi
sect. He came to be known as Swami Jambeshwar Maharaj. He laid down tenets (including
a ban on killing animals, a ban to the felling of khejri and other trees) for his followers.
Once the Maharaja of Jodhpur sent his men to the area around the village of Jalnadi
to fell the trees as he required wood for building a new palace. When Amrita Devi (a
Bishnoi rural woman) saw this, she rushed out to prevent the men and hugged the first tree,
but the axe fell on her. Before dying, she uttered the now famous couplet of the Bishnois,
‘A chopped head is cheaper than a felled tree’.
To prevent the Maharaja’s men from felling the trees, people from 83 surrounding villages
rushed to the spot and by the end of the day more than 350 had lost their lives.
When the Maharaja heard about this, he was filled with regret and came to the
village to personally apologize to the people. He promised them that they would never
again be asked to provide timber to the ruler, no khejri tree would ever be cut, and hunting
of animals would be banned near the Bishnoi villages. The village of Jalnadi thus came to
be called khejari. The Bishnois have proved that human lives are a small price to pay to
protect the wildlife and the forests around them.
3.4.2. Mining:
Mining is the extraction (removal) of metals and minerals from the earth.

A. Sustainable Mining
Extraction and beneficiation of raw materials has to be
Environmentally compliant (agreement or as per rules)
Socially acceptable ‘‘Sustainable”
Economic
A mining operation is socially acceptable if
It obeys standards in occupational safety and health
It is accepted by the society
It obeys national and international guidelines and laws
It provides resettlement help
It considers cultural and social constraints
It provides suitable working conditions for the workers
 A mining operation is economic if
It fulfills the needs of the society with material and immaterial goods
It is working for the long-term maximization of revenues and profit
A mining operation is environmentally compliant if
It does not impose any harm to the environment.

B. Mining Process and the Environment
Some of the major environmental impacts of mining are a result of associated
mining operations as summarized below.
Mining process and the environment
C. Environmental Impacts of Mining
Some of the major environmental impacts of mining are the following:
Ecological Impacts
Degradation of Land: Due to leaching out of toxic elements, the growth of
vegetation is adversely affected. Loss of fauna and flora is also observed.
Socio-economic Impacts
Pollution of Water Resources: Even when drainage is controlled, some
leaching and release of harmful elements (e.g. Pb, Cd, etc.) into the surface
and groundwater occurs. It affects the ecosystem stability adversely due to
alterations in water quality and availability.
Pollution of Air: Mining processes emit dust and gases which cause air
pollution. These air pollutants have adverse impacts on historical
monuments and religious places.
Problems in Rehabilitation of Affected Population: It is one of the
biggest problems due to economic constraints.
 To sum up,
Mines Always cause
Environmental
impacts……
But... it is usually
cheaper to prevent
the impacts than to
deal with them after
they have already
happened. It is easier
to prevent the
impacts if one
knows about them in
advance.
Impacts of mining activities
D. Impact of Mining Activities on Labourers
Studies on mining activities in the Aravalli's have shown that
Labourers are not provided with any health care
Tuberculosis, silicosis and other lung diseases are very common
Diseases make labourers invalid and even kill them by the age of 40
The condition of women workers (30–40%) and child labourers (10–15%)
is the worst.
E. Impact of Mining on the Culture and Lifestyle of People
From the gold and copper project, 1000 m3 of conc. cyanide were released
into a river in 1984 on the OK Tedi Island in new Guinea.
It caused extensive environmental damage, devastated the ecosystem and
destroyed the culture and lifestyle of the native Wopkaimin people.
Case Studies:
(i) Impact of Coal Mining on Vegetation
Meghalaya, one of the seven states of North-East India, is honoured with rich
natural vegetation as well as large reserves of mineral resources.
In the early 1970s, coal mining was initiated in the Jaintia Hills district of
Meghalaya. Since then, mining and the area affected by it is increasing day by day.
The dense forest areas were converted into open forests and the considerable area
of the forests was converted into a nonforest.
Extensive coal mining has led to landscape damage and damage to the
biological communities in enormous ways. The number of trees and shrub species
drastically decreased due to mining. The unfavourable habitat conditions prevailing
in the coal-mining areas has reduced the chances of regeneration of species,
thereby, reducing the number of plant species in the mined areas.
(ii) Marble Mining and Drying of Lakes in Rajasthan
The Aravalli Hills are the lifeline of Haryana, Rajasthan, and Gujarat. They
control the climate and drainage systems of the region. The hills also act as a
watershed for the region. The hills are also known for their rich deposits of teak,
marble and granite. About 1,75,000 workers are employed in mining and related
industries. About 9700 industrial units are connected with mining in Rajasthan
alone.
Over the past 20 years, the forest cover has been depleted by 90% in Rajasthan
due to large-scale mining. When the mines reach below the underground water l
evel, a cone of depression is formed that sucks water from the surrounding areas,
drying up wells and lakes and affecting agriculture.
The Rajasamand Lake in Rajasthan had not dried up for at least 300 years.
However, in 2001, this finally did happen because of a decade of marble mining in
the Rajnagar area. While mining has led to the depletion of water, mining waste
has destroyed fertile land.
(iii) Jhansi Open-Cast Mining Site: Uttar Pradesh, India
The Bundelkhand region occupying about 71818 km2 in Uttar Pradesh is known
for its rich deposits of graphite, saltpetre, sand, etc. Presently there are more than
300 active mining sites in the Jhansi district alone.
Mining and its allied activities significantly contributed towards infrastructure
development and raising the living standards of the people.
Deforestation, dust generation, noise, air and water pollution as well as
resource depletion are common hazards associated with open-cast mining widely
prevalent in the Jhansi region.
3.4.3. Dams and their Effects on Forest and Tribal People:

A dam is a huge and giant barrier constructed across a river to obstruct its
natural flow. Consequently, an enormously large artificial lake is created to store
water.
The water thus stored is utilized for multipurpose services such as power
generation, irrigation, flood and drought control, etc.
Construction of dams in countries like India and China displace a large number
of people because of the high population densities of these countries.
In India, dams account for 75–80% of displacement of about 4–5 crore people.
Out of the total people displaced, only 25% have been rehabilitated so far.
Tribal people are economically, socially and politically the weakest and the
most deprived community in India.
A. Problems associated with effects of dams on tribal people are:
No Human Rights
Human rights violations create unrest among tribals.
No Basic Amenities
They are forced to migrate to urban slums in search of employment. They
become landless labourers in rural areas.
A majority of tribal people end up with less income than before, less
resources of the common people, inferior houses, etc.
They are forced to live without drinking water, sanitation, health care, and
other basic amenities.
No Benefit Sharing
They hardly get to share the benefits of development projects that cause
their displacement.
 No Home
Tribal people have been forced to leave their ancestral homes and go
elsewhere.
No Cultural Identity
Tribal communities get dispersed, traditional support systemsget broken
and cultural identity gets devaluated because of dams.

Problems associated with effects of dams on tribal people: Loss of
B. Major effects of Dams on Forests are:
All major dams are constructed in mountainous regions, where there is plenty of
rainfall. These places are covered with rich vegetation and forests.

The forests area which is supposed to get submerged is cleared off by the
contractors.
The forest is also cleared for approach roads, offices, residences and for storage
of construction material.
As more and more workers occupy the dam sites, forests are destroyed for getting
fuel and timber.
Irrecoverable Loss to Ecosystems and Biodiversity Forest fragmentation
causes serious irrecoverable loss of species and ecosystems. This is because some
species of animals and plants require large continuous areas of similar habitat to
survive.
3.5. Water Resources:
Water resources are sources of water that are useful or potentially useful to humans.
Water is a prerequisite for the existence of life. Plants, animals, and human beings
cannot survive without water.
Water is used in agricultural, household, industrial, recreational and environmental
activities.
Water is essential for economic growth, environmental stability, biodiversity
conservation, food security and health care.

A. The Water Cycle:

Water cycle is the continuous movement of water above and below the surface of the
earth. It is driven by the sun. The sun heats water in seas and oceans.
Water evaporates into the air as water vapour. Snow and ice can sublime directly into
water vapour. Rising air currents take the water vapours into the atmosphere where
cooler temperatures help them to condense into clouds.
 Air currents move clouds; they collide, grow, and fall out of the sky as precipitation.
Some precipitation falls as snow, and can accumulate as ice caps and glaciers.
Most water falls back into the oceans or onto land as rain where the water flows over
the ground as surface run-off. Much of the run-off is soaked into the ground as
infiltration.
Some run-off is stored as fresh water in lakes. Some run-off enters rivers in valleys in
the landscape. Some water infiltrates deep into the ground and replenishes aquifers.
This helps in the long-term storage of freshwater.
Some groundwater finds openings in the surface of land and freshwater springs come
out. Some rainwater flows through rivers back into the ocean, where the water cycle
begins again.
B. Sources of Water:
97.5% of water on the earth is salt water in oceans. Only 2.5% is fresh water. Sources
of fresh water are briefly described below:

Surface Water: Water in a
lake, river or freshwater
wetland is known as surface
water.
Groundwater: Fresh water
located in the pore space of
soil and rocks is called
groundwater.
Ice Caps and Glaciers:
Fresh water from ice caps
and glaciers is relatively
inaccessible.
Distribution of the earth’s water
C. Availability of Water:

World’s water content
 Water availability versus population

Availability of Water in India
India is the wettest country in the world, but rainfall is highly uneven with space and time.
Rainfall is high in the North-East but extremely low in Rajasthan.
Out of 4000 billion cm3 rainfall received, about 600 billion cm3 is put to use so far.
With 16% of the world’s population, India has only 4% of global water resources.
The city of the Delhi gets 60 hours of rain a year, and only 11 hours of it are contained
while the rest is wasted. Every monsoon we see flooded underpasses and buses floating by.
D. Causes of Water Crisis in the World
Growing population and with better lifestyles, per capita use of fresh water is
increasing, causing shortage of water.
Spatial and temporal variations in available water is also responsible for water crisis.
Freshwater resources are reduced by pollution. Industrial wastes, chemicals, human
waste and agricultural wastes (fertilizers, pesticides and pesticide residues) are
disposed off within water.
Increase in extreme weather conditions like floods, droughts, typhoons, cyclones,
etc., are also responsible for worsening of water quality and availability.
Recently, it is estimated that
✓ Climate change will account for about 20% of the increase in global water scarcity
✓ 50% of the population of developing countries are exposed to polluted water
sources
(E) Importance of Water:

Next to air, water is the most essential thing for our survival. We must drink water
to avoid dehydration which means less or insufficient levels of water and important
body salts of sodium and potassium in our body.
The kidneys, brain, heart and other important body organs cannot function properly
without salt and water.
Water is also helpful in maintaining the relatively constant body temperature
through the homeostasis process. It helps in avoiding upsetting of metabolic
reactions by preventing sudden changes in temperature.
Water helps in the digestion process. Different types of food products, after being
broken down to simple molecules (e.g. large starch molecules are broken down to
simple sugars) are solubilized in the universal solvent ‘water’. Different enzymes
facilitate this digestion process.
 Oxygen gas is also dissolved in water to some extent. This Dissolved Oxygen (DO)
helps in the respiration process of many organisms who live in water and spend
most of their time underwater.
“Life is impossible without water. It is needed for health, ecosystem services,
economic development, poverty reduction, protection of greenery, production of
food and imparting of aesthetic beauty.”

(F) Impacts of Over-utilisation of Underground and Surface Water
The over-utilisation of underground and surface water has the potential to alter,
sometimes irreversibly, the integrity of freshwater ecosystems. Some of the major
impacts are summarised below:
Loss of Integrity of Freshwater Ecosystems: Human activities for
infrastructure development like creation of dams, land conversion, etc., are
responsible for this loss of integrity of freshwater ecosystems. Water quality and
quantity, fisheries, habitats, etc., are at risk due to this loss of integrity.
 Risk to Ecosystem Functions: Population and consumption growth increases
water abstraction and acquisition of cultivated land. Virtually all ecosystem
functions including habitat, production and regulation functions are at risk.
Depletion of Living Resources and Biodiversity: Overharvesting and
exploitation causes groundwater depletion, collapse of fisheries. Production of
food, quality and quantity of water and supply of water gets badly affected by
these depletions of living resources and biodiversity.
Pollution of Water Bodies: Release of pollutants to land, air or water alters
chemistry and ecology of water bodies. Greenhouse gas emissions produce
significant changes in run-off and rainfall patterns. Because of water pollution,
water supply, habitat, water quality, food production, climate change, etc., are at
risk.
3.5.1. Uses and Overuses of Water Resources
(A) Uses of Good-Quality Water
Good-quality water is needed for all direct or indirect uses of water as illustrated
below:

Direct and indirect uses of water resources by humans and ecosystems
 According to the Union Ministry of Water Resources (MoWR), 80 per cent of India’s
utilizable water is devoted to agriculture, mostly for irrigation.
Demand from the domestic sector is about 5% of the annual freshwater withdrawals
in India. The industrial sector in India is the second largest user of water.
As a result of growing sectoral demands and declining water supplies, competition is
growing rapidly.
From public systems, allocation of water is not based on fundamental rights
consideration or social, economic or environmental considerations, Thus, water
allocation is inequitable. Growing inequity in access to and control over water leads
to conflicts among different sectors.
The poor need water for both domestic as well as productive purposes which include
growing food, fruit, vegetables, rear livestock, etc.
 The rich residents of cities consume around 200 litres per capita per day. It is
believed that finding ways of providing similar quantity of water in support of the
livelihoods of the rural poor is vital.
India’s supply of water is rapidly decreasing mainly due to mismanagement of water
resources, although over-extraction and pollution are also significant contributors.

(B) Sectoral Demand of Water:
As per the ministry of
Water Resources (MoWR)
assessment, 2000; water
requirements for various
sectors in India is:
Over-exploitations of water resources and the problem of availability of safe drinking
water:
Excessive Withdrawal from Surface Waters Size of the sea is shrinking (e.g. the
Aral sea in the former Soviet Union) primarily by the diversion of the inflowing
rivers to irrigate water-intensive cotton and rice crops. In 2007, about 60% of the
Aral Sea’s volume had been lost, its depth had declined by 14 metres. Moreover, its
salt concentration had doubled.
Inefficient Use of Freshwater Excessive consumption by individuals, leakage in
water delivery systems, inefficient use by industry and poor irrigation practices can
all contribute to situations where there is not enough water for all uses.
Excessive Withdrawal of Water from Underground Aquifers Excessive
freshwater abstraction along much of the west coast of India has allowed sea water to
enter aquifers. It resulted in making the water saline and unfit for human use. The
above problem has worsened due to leaching of excess irrigation water containing
pesticides, fertilizers, etc., into these aquifers.
(C) Water Conservation

“ Water conservation is the most cost-effective and eco-friendly way to reduce our
demand for water.”
Need for Water Conservation:
On an average, a citizen in most parts of the world is allocated 2.5 gallons of water
per day for sustainability.
However, the average American citizen uses 80–100 gallons of water per day. The
poor do not have access to safe drinking water.
More than 4000 children are dying every day as a result of diarrhoeal diseases
caused from unsafe drinking water, lack of access to sanitation and inadequate
availability of water. Thus, it is very essential to conserve water.
Measures to Conserve Water:
Recharge groundwater by harvesting rainwater.
Use water wisely for household, agricultural and domestic purposes.
Reuse water whenever possible. For example, waste water after bath can be used for
the toilet.
Avoid transmission and distribution losses by checking leaks in pipes, hoses, etc.
Prevent flow of untreated sewage to lakes and rivers. This will reduce the likelihood
of water pollution and help in water conservation.
Collect water by building dams and reservoirs, and digging wells.
Use drip irrigation, precision sprinklers for agriculture. Practice organic farming.
Adopt fairer policies for treatment, access and pricing of water.
Prevent flow of industrial effluents to natural water resources to avoid water pollution.
Do protect forests to protect rivers, lakes, wells and other sources of water.
(D) Quality Aspects

Impacts of Poor Water Quality
Poor water qualities are responsible for public health hazards,
damage to ecosystems, and
adverse economic consequences.
A good status of water biology and healthy aquatic organisms are necessary for
obtaining a good status of water quality.

Characteristics of a Good-Quality Water
It is transparent, colorless and odourless.
It has sufficient oxygen concentration for marine life to survive.
It is free from bacteriological contamination.
It is free from any water pollution.
It is free from excessive nutrients like N, P, etc., which are responsible for
eutrophication.
It is fit for the intended use.
(E) Self-Purification of Rivers
A variety of plant and animal species live in seas and rivers. If pollution does not
attain a critical level, water can purify itself, i.e. progressively eliminate polluting
agents.
The phenomena of filtration and oxidation, combined with the action of organisms
(insects, bacteria, plants, etc.) living in the water and on the banks helps water
maintain its quality and preserve its ecosystem’s balance.
Various river-self purification mechanisms are:
(i) Phyto-remediation Aquatic plants and vegetation on the river banks absorb (nitrate,
phosphate and other nutrients) and remove pesticides and heavy metals from water.
In this way quality of water in the river is largely improved.
(ii) Aeration When a river runs through hills, turbulence mixes air into water increasing
the dissolved oxygen (DO). The increased DO concentration facilitates many
chemical and microbiological processes in water to reduce the pollutant
concentration.
(iii) Sedimentation In this mechanism, sand in the riverbed acts as a sink for the
pollutants. From the hills, when river reaches flat lands, it spreads, its velocity
reduces and suspended pollutants settle on the sand bed.
(iv) Adsorption Pollutants are adsorbed onto sand particles, plant surfaces, rocks, etc.,
and thereby their concentrations get reduced in the river water.
(v) Dilution When a polluted river is joined by less polluted tributaries or during the
rainy seasons, the volume of water in the river is increased. It reduces the
concentrations of pollutants by dilution process.
vi. Floatation After rapid mixing of water in falls, air bubbles act as vehicles to lift
many pollutants to the water surface in the form of froth (or a layer of foam). This
froth is exposed to the atmosphere, and it facilitates oxidation of pollutants to less
harmful forms. The top layer is also directly exposed to sunlight; so either by
increased temperature or due to various photochemical reactions, volatile organic
compounds are removed from the top layer. At different sections of the river, various
artificial traps help in the removal of this froth and thus rivers get self-purified.
vii. Microbial Degradation The shallow and turbulent water results in high aeration of
water. It helps in growth of bacteria and other microorganisms. They help in river
purification by microbial degradation of pollutants.
(F) Major Water-Quality Issues:

Wastes introduced by humans into rivers, lakes, groundwater aquifers and the oceans
modify the environmental water quality and make huge quantities of water unsuitable
for various uses.

(G) Major Factors Responsible for Water-Quality Degradation:
(i) Insufficient and incomplete treatment of domestic and industrial wastewater
(ii) Eutrophication
(iii) Pathogens, and pesticide contamination
(iv) Stagnation of domestic sewage and contamination of groundwater
Important quality issues of water
(H) Water-Borne Diseases
Water-borne diseases are illnesses caused by consuming water contaminated by
pathogenic microorganisms.

Illnesses caused by consuming contaminated water
 Often lack of access to hygienic water, poor sanitation and rise in population of
pathogenic microorganisms like protozoa, viruses, bacteria and intestinal
parasites breeding in on water are considered the main causes of water-borne
diseases.
According to the World Health Organization, diarrhoeal disease is responsible
for the deaths of 1.8 million people every year and a majority of them are
children in developing countries.
A few water-borne diseases are summarized as:
 The best ways to prevent water-borne diseases are:
(i) avoid drinking untreated water,
(ii) avoid consuming undercooked food,
(iii) maintain good personal hygiene (e.g. wash hands before eating), and
(iv) educate for clean sanitation.
(I) Fluoride Problem in Drinking Water
At low concentrations in drinking water, fluoride has beneficial effects on teeth.
But excessive exposure to fluoride in drinking water can give rise to number of
adverse effects.
Although the concentration (mg/litre) of fluoride added to water can be controlled,
but we cannot control the dose (mg/day). This is because one cannot control how
much water people drink or how much fluoride they get from other sources.

(i) Sources of Fluoride
(a) Fluoridated water supplies
(b) Food processed with fluoridated water
(c) Mouthwash enhanced with fluoride
(d) Toothpaste enhanced with fluoride
(e) Food supplements
(ii) Fluoridation is not Necessary
(a) The level of fluoride in mother’s milk is 0.004 ppm. It means a bottle-fed
baby, where fluoridated tap water (with 1 ppm fluoride) is used to make up
the formula milk, will get 250 times more fluoride than nature intended.
(b) Fluoride works from the outside of the tooth, not from inside the body, so it
is not required to swallow fluoride or drink fluoridated water.
(iii) Fluoride’s Dangers
Fluoride damages teeth, bone, brain and endocrine system. It may cause
osteosarcoma.
(a) Fluoride damages the teeth: A permanent discoloration and mottling of the
tooth enamel (dental fluorosis) is caused by a child’s ingestion of fluoride
(0.5–1.5 ppm) before its permanent teeth have erupted.
(b) Fluoride damages the bone: In an area of high natural levels of fluoride
(1.5–5.5 ppm), fluoride can weaken bone and increase the risk of fractures.
c) Fluoride damages the brain: Fluoride lowers the IQ of children, even when
present at 1.8 ppm in water. It is apparent that fluorides have the ability to
interfere with the functions of the brain.
Dangers of fluoride consumption:
(iv) Defluoridation of Water
Defluoridation of water can be carried
out by
(a) Reverse osmosis filtration
(b) Activated alumina defluoridation
filter
(c) Nalgonda technique
(J) Pesticide Removal Methods from Drinking Water
 Water contaminated or suspected of being contaminated by pesticide and
synthetic/volatile organic compounds can be purified using following methods
3.5.2. Floods

Waterways are formed slowly over time, and their size is proportionate to the amount
of water that normally accumulates in that area.
Sometimes, due to excessive runoff from precipitation or snowmelt or by coastal
storm surges or other tidal phenomenon, there is suddenly a much greater volume of
water.
As a result, the normal waterways overflow, and the water spreads out over the
surrounding land. This anomalous accumulation of water in an area of land is called
flood.
Flood can be defined as a temporary rise of the water level, as in a river or lake or
along a seacoast, resulting in its spilling over and out of its artificial or natural
confines onto land that is normally dry or flood is a temporary covering by water of
land not normally covered by water.
(A) Effects of Flood

The effects of flood are briefly described below:
(i) Primary Effects Flood can cause either physical damage or casualties.
(a) Physical Damage: Flood can damage any type of structure resulting in physical
damage to canals, bridges, sewerage systems, roadways, cars, buildings, etc.
(b) Casualties: Humans and animals die due to drowning. Floods can also cause
casualties through epidemics and water-borne diseases. The spawning grounds
for fish and other wildlife can become polluted or completely destroyed.
(ii) Secondary Effects Secondary effects of floods are briefly summarized below:
(a) Contamination of Water: Clear drinking water becomes scarce because of
contamination of water due to floods.
(b) Spread of Water-borne Diseases: Floods are responsible for unhygienic
conditions leading to various diseases.
c) Loss of Harvest: The entire harvest can be lost due to floods leading to shortage
of food crops and this badly affects the food supplies.
d) Death of Some Nontolerant Tree Species: Floods can lead to suffocation and
death of some nontolerant tree species.

(iii) Tertiary Effects / Long-term Effects
Floods are responsible for food shortage, leading to price increases. They are
also responsible for temporary decline in tourism.
Money is also, needed for rebuilding any type of structure damaged by flood.
All the above effects (where economic hardship in concerned) is discussed in
tertiary effects or long-term effects.
(B) Benefits of Floods
The more frequent and smaller floods can bring following benefits:

(i) Water Availability: Floods helps in recharging of groundwater. Flood
waters provide much-needed water resources in arid and semi-arid regions
where precipitation events are unevenly distributed throughout the year.
(ii) Ecosystem Services: Specially freshwater floods play an important role in
maintaining ecosystems in river corridors and in maintaining floodplain
biodiversity.
(iii) Increase in Soil fertility: Floods help in making the soil more fertile by
providing nutrients to soil.
(iv) Improved Fisheries: Flooding adds a lot of nutrients to lakes and rivers
which help in improved fisheries for some years. Fish, like weather fish,
make use of floods to reach new habitats.
 (v) Benefits to Birds: Birds profit from the boost in production caused by
flooding.
(vi) Higher Viability of Hydro-energy Projects: The viability for hydrological
based renewable source of energy is higher in flood-prone regions.

(C) Flood Disaster Impact Minimisation

(i) If it has been raining hard for several hours, or steadily raining for several
days, individuals must listen carefully to the radio or TV flood forecasts issued
by the Central Water Commission.
(ii) They should listen to and follow the instructions of the emergency services.
(iii) They should extend all possible help to the administrative and engineering
agencies of the states/union territories to take appropriate measures.
3.5.3. Drought
Drought may be defined as the deficiency of rainfall (relative to the statistical multi-
year average for a region ) over an extended period of months or years.

(A) Types of Drought

(i) Meteorological Drought
It is brought about when there is a prolonged period with less than average
rainfall. As per the India Meteorological Department (IMD),
meteorological drought occurs when the seasonal rainfall received over an
area is less than 75% of its long-term average.
 The drought can be classified as ‘moderate’ or ‘severe’ depending on the
rainfall deficit between 26% to 50% or exceeds 50% respectively. Usually,
meteorological drought precedes the other kinds of drought.
(ii) Agricultural Drought
It is a drought that affects crop production or the ecology of the range. It is
caused by extended period of below-average rainfall resulting in a shortfall
in water for the crops.
It is typically witnessed after a meteorological drought but before a
hydrological draught.
(iii) Hydrological Drought
It is brought about when the water reserves available in sources such as
reservoirs, lakes or aquifers fall below the statistical average.
It tends to show up more slowly because it involves stored water that is used
but not replenished.
(B) Consequences of Drought The impacts of drought are

(i) Impact on Agriculture: Droughts are responsible for diminished crop growth
or diminished production yields due to lack of water for irrigation. Famine
may also be caused.
(ii) Impact on Environment: When drought hits an area suffering from
desertification and erosion, dust storms and/or dust bowls result which further
erode the landscape. Drought also affects both terrestrial and aquatic wildlife
through habitat damage.
(iii) Impact on Health: Drought is responsible for malnutrition, dehydration and
related diseases. Drought can also reduce water quality, because lower water
flows reduce dilution of pollutants and increase contamination of remaining
water sources.
(iv) Social Impacts: Subsistence farmers are forced to migrate during drought
because they do not have alternative food sources.
 Mass migration results in internal displacement and international refugees.
Droughts are also responsible for snake migration and increases in
snakebites.
In totality, a situation of social unrest arises because of drought. A war can
also happen over natural resources including water and food.
(v) Economic Impacts Droughts lead to reduced electricity production due to
reduced water flow through hydroelectric dams and insufficient available
coolant for power stations. Droughts also lead to shortages of water for
industrial users
Effects of drought
(C) Strategies for Mitigation of Drought Impacts

Society’s vulnerability to drought is minimized through the following actions:
(i) An artificial technique of cloud seeding helps in inducing rainfall.
(ii) For consumption or irrigation, desalination of sea water can be done in times of
scarcity.
(iii) Carefully planned crop rotation can help to minimize soil erosion. This also allow
farmers to plant less water-dependent crops in drier years.
(iv) Collection and storage of rainwater through rainwater harvesting is very useful.
(v) Regulating the use of water-intensive home maintenance tasks and the use of
sprinklers, hoses, etc., on outdoor plants.
(vi) Redirecting rivers for irrigation in drought-prone areas.
(vii)Treatment and purification of sewage wastewater for reuse.
(viii) Continuous observation of rainfall levels and comparisons with current usage
levels can help prevent man-made drought.
3.5.4. Conflicts Over Water
Water might be the source of the world’s next big conflict. This is because fresh water
availability is limited but its demand is rising day by day.

Demand for water

(i) Infrastructure Failure The cost and environmental risks due to failure of drinking
and wastewater infrastructure are very high, costing billions of rupees.
(ii) Rapid Urbanization It requires significant investment in water infrastructure in
order to deliver water to individuals and to process the wastewater so as to avoid
unacceptable public health risks.
(iii) Population Growth The demand of water for residential and industrial purposes
increases with increase in population.
(iv) Increasing Affluence Increasing affluence especially in India and in China,
inevitably means more water consumption. Expansion of business activity requires
more water supply.
(v) Climate Change Climate change poses a series of risks to water availability as a
result of the following:
(a) Rising temperatures could increase the rate of evaporation from surface waters
and reservoirs and lead to loss of freshwater held in glaciers.
(b) Increased rainfall might come in the form of storms that lead to floods.
(c) Climate change could increase annual precipitation and make more freshwater
available in some places leading to difficulty in water management systems.
 Where water crosses cultural, economic, political or legal boundaries, the stage is set
for disputes between different users.
The users try to safeguard access to a vital resource, while protecting the natural
environment.
Management and transformation of water conflicts require implementation of right
strategies for anticipation, addressing and mediation between competing users.
If the strategies are not implemented, the conflicts over water are likely to become
more frequent, more intense and more disruptive around the world.
Water conflicts in India:
Water conflicts in India can be classified as per the following themes:
Conflicts over
(a) equity, access and allocations,
(b) water quality,
(c) dams and displacement,
(d) privatization,
(e) contending water uses,
(f) sand excavation and mining,
(g) trans-boundary conflicts, and
(h) micro-level conflicts are also present.
Some specific examples of conflicts over water:
(i) Conflict between Poor and Rich The rural peasants are poor and only require a pot
full of drinking water. The urban elite is rich and uses large quantities of water for
meeting the requirements of water-intensive sewage systems, space cooling,
gardening, etc. This results in conflict.
(ii) Conflicts between Agricultural Usage of Water Conflict also exists between
water-intensive cultivation of commercial crops for high cash returns and wise water
use for protective irrigation of necessary food crops essential for survival.
(iii) Interstate Conflicts Sometimes water projects of upstream states influence the
quantity and quality of water flow in the basin. This reduces the possibilities of
water use by downstream states resulting in inter-state conflicts.
(iv) Intrastate Conflicts State-planned extraction of timber or minerals in the river
catchment affect the river flow and generate conflicts downstream. State-planned
agricultural production based on large irrigation projects to generate marketable
surpluses of cash crops conflicts with people’s needs for local food production.
(v) Across Borders Conflicts India, Bangladesh and Nepal are disputing the best use of
water of the Ganges–Brahmaputra basin. India and Nepal want to exploit the
basin’s huge hydroelectric power-generating potential, whereas Bangladesh wants
the water management in such a way so as to minimize water shortages during dry
months and flooding during monsoon months.
3.6. Heating of earth and circulation of air; air mass formation and
precipitation:
3.6.2. Heating of Earth:
 Atmosphere is more transparent to
incoming short-wave radiation than
to outgoing long-wave radiation
The temperature of a body
determines wavelengths of energy
emitted.
Solar radiation has high energy
(shortwave) that readily penetrates
the atmosphere.
Earth emits low-energy (longwave)
radiation that is absorbed by
different gases in the atmosphere
 Energy in = energy out
Half of solar radiation reaches
Earth (latent & sensible heat).
The atmosphere is transparent to
shortwave but absorbs longwave
Radiation (greenhouse effect).
The atmosphere is heated from
the bottom by longwave radiation
and convection.
 The atmosphere is heated from the
bottom.

Therefore it is warmest near the bottom,
and gets colder with increasing
elevation.

Except the stratosphere is heated from
the top – ozone absorption of incoming
UV.

Mesosphere and Thermosphere have
little impact on the biosphere.
 Earth rotates on its axis from west to east, the Moon and the Sun (and all other
celestial objects) appear to move from east to west across the sky. Because of
the Earth’s magnetic field, it rotates from west to east.
Earth rotation appears counterclockwise when viewed from above the North
Pole, and appears clockwise when viewed from above the South pole.
It is common to all the planets in our solar system except Venus and Uranus,
according to NASA
3.6.2. Air Pressure (High or Low):

Standing on the ground and looking up, you are looking through the atmosphere. It
might not look like anything is there, especially if there are no clouds in the sky. But
what you don’t see is air – lots of it. We live at the bottom of the atmosphere, and
the weight of all the air above us is called air pressure.
Above every square inch on the surface of the Earth is 14.7 pounds of air. That means
air exerts 14.7 pounds per square inch (psi) of pressure at Earth’s surface. High in the
atmosphere, air pressure decreases. With fewer air molecules above, there is less
pressure from the weight of the air above.
Pressure varies from day to day at the Earth’s surface - the bottom of the atmosphere.
This is, in part, because the Earth is not equally heated by the Sun. Areas where the
air is warmed often have lower pressure because the warm air rises. These areas are
called low pressure systems. Places where the air pressure is high, are called high
pressure systems.
 Air near the surface flows down and
away in a high pressure system (left)
and air flows up and together at a low
pressure system (right).
A low pressure system has lower
pressure at its center than the areas
around it. Winds blow towards the
low pressure, and the air rises in the
atmosphere where they meet. As the
air rises, the water vapor within it
condenses, forming clouds and often
precipitation.
Because of Earth’s spin and the Coriolis effect, winds of a low pressure system swirl
counterclockwise north of the equator and clockwise south of the equator. This is
called cyclonic flow. On weather maps, a low pressure system is labeled with red L.
 A high pressure system has higher pressure at its center than the areas around it.
Winds blow away from high pressure. Swirling in the opposite direction from a low
pressure system, the winds of a high pressure system rotate clockwise north of the
equator and counterclockwise south of the equator. This is called anticyclonic flow.
Air from higher in the atmosphere sinks down to fill the space left as air is blown
outward. On a weather map, you may notice a blue H, denoting the location of a high
pressure system.
Air Pressure was measured by using Barometers, how much the Mercury liquid
present in barometer was pushed by the air (pressure) and the measurement was
made/denoted in Millibars (mb)
Air Pressure depends on Temperature and Density of the air. If pressure increases on
air, the temperature of air increases and if pressure decreases automatically the
temperature of air decreases.
This explains why air gets colder at higher
altitudes, where pressure is lower.
3.6.3. Circulation of Air/Atmospheric Circulation:
Even with disruptions like weather fronts and storms, there is a consistent
pattern to how air moves around our planet’s atmosphere.
This pattern, called atmospheric circulation, is caused because the Sun heats
the Earth more at the equator than at the poles. It's also affected by the spin of
the Earth.
In the tropics, near the equator, warm air rises. When it gets about 10-15 km (6-
9 miles) above the Earth surface it starts to flow away from the equator and
towards the poles.
Air that rose just north of the equator flows north. Air that rose just south of the
equator flows south. When the air cools, it drops back to the ground, flows back
towards the Equator, and warm again.
The, now, warmed air rises again, and the pattern repeats. This pattern, known
as convection, happens on a global scale. It also happens on a small scale
within individual storms.
 Even with disruptions like weather fronts and storms, there is a consistent
pattern to how air moves around our planet’s atmosphere.
This pattern, called atmospheric circulation, is caused because the Sun heats
the Earth more at the equator than at the poles. It's also affected by the spin of
the Earth.
In the tropics, near the equator, warm air rises. When it gets about 10-15 km (6-
9 miles) above the Earth surface it starts to flow away from the equator and
towards the poles.
Air that rose just north of the equator flows north. Air that rose just south of the
equator flows south. When the air cools, it drops back to the ground, flows back
towards the Equator, and warm again.
The, now, warmed air rises again, and the pattern repeats. This pattern, known
as convection, happens on a global scale. It also happens on a small scale
within individual storms.
Air in the atmosphere moves around the world in a
pattern called global atmospheric circulation
 But because Earth is spinning, the air that moves north and south from the equator
also turns with the spin of the Earth. Air going north turns to the right. Air
traveling south turns to the left. The power of Earth’s spin to turn flowing air is
known as the Coriolis Effect.
If the Earth didn’t spin, there would be just one large convection cell between the
equator and the North Pole and one large convection cell between the equator and
the South Pole. But because the Earth does spin, convection is divided into three
cells north of the equator and three south of the equator – Hadley Cell, Ferrel
Cell and Polar Cell.
Formation of Hadley Cell (1):

Insolation in tropical areas causes warm air
to rise and spread polewards, carrying heat
energy.

Formation of Hadley Cell (2):
Air cools and begins to fall at about 30ºN and 30ºS of Equator.
Cooled air returns to the Equator.
This circulation of air is caused by solar heating.
Heat energy is transferred from the
Equator to subtropical latitudes.
It is called the HADLEY CELL
Formation of Polar Cell (1):
Intensely cold, dense air sinks at the
poles, then blows as surface winds
towards the Equator.

Formation of Polar Cell (2):

At about 60ºN and 60 ºS, the cold polar air is
warmed in contact with the earth’s surface.
This warmed air rises and returns polewards,
carrying heat energy.
This circular motion is called POLAR CELL
Formation of Ferrel Cell (1):

The Hadley Cell is driven by
differences in heat energy at the
Equator.
As the air in the Hadley Cell
falls at about 30ºN and 30ºS, it
pulls the air beside it down as
well, due to friction
Formation of Ferrel Cell (2):

The Polar Cell is driven by differences in
heat energy. Cold polar air falls and spreads
towards the Equator.
As the air in the Polar Cell rises at about
60ºN and 60ºS, it pulls the air beside it up as
well, due to friction.
Formation of Ferrel Cell (3):

Unlike the Hadley and Polar Cells, the
Ferrel Cell is not driven by differences in
heat energy.
The Ferrel Cell is caused by friction
where air is in contact with the other two
cells.
The Hadley Cell drags air down at about
30ºN and S
The 3 Cell together:
The transfer of Heat Energy from Equatorial to Polar Areas:

Air carrying energy from the Equator in the
Hadley Cell comes into contact with air in the
Ferrel Cell, there is a transfer of heat energy
into the Ferrel Cell.
There is a similar transfer of heat energy from
the Ferrel Cell to the Polar Cell.

In this way, heat energy is transferred from the
Equator, where there is a surplus of energy, to
the poles where there is a deficit.
The corresponding movement of colder air:

In the Polar cell cold air from polar
regions flows to mid-latitudes as polar
easterly winds.
In the Ferrel Cell there is a movement of
cold air at high altitude.
In the Hadley Cell, cooler air moves from
the subtropics to the Equator.
Pressure Belts:

Rising air at the equator causes the
equatorial belt of low pressure.
Descending air at about 30oN and 30oS
causes the sub-tropical belt of high
pressure.
Rising air at about 60oN and 60oS causes
a mid-latitude belt of low pressure.
Descending air at the poles causes the
polar high pressure areas
Surface wind patterns:

Winds always blow from high pressure to
low pressure.
They are deflected because of the Coriolis
Force which come about because of the
rotation of the earth.
Winds in Northern Hemisphere are
deflected to the right.
Winds in the southern hemisphere are
deflected to the left.
These wind belts shift seasonally.
Seasonal shift of the cells or Seasonal shift of Radiation on Globe:
Tilt of the Earth’s axis towards or away from the sun creates the seasons

When the north pole tilts toward the sun, it gets
more radiation – more warmth during the
summer

When the north pole tilts toward the sun, the south pole
tilts away So when it’s summer in the north, it’s winter in
the south.
 When the north pole tilts away from the sun, it
gets less radiation – So it’s colder during the
winter

When the north pole tilts away from the sun, the
south pole tilts toward it.
When it’s winter in the north, it’s summer in the
south.
Air Circulation patterns are modified by the distribution of oceans and continents:

High heat capacity of water and ocean currents buffer ocean temperatures

Land temperatures fluctuate more, especially in higher latitudes

These differences in surface energy balance influence air movements, and create
prevailing winds

In summer at 60 ºN & S, air descends over cold ocean (high pressure) and rises over
warm land (low pressure)
Cool equator-ward flow of air on West coast of continents
Warm poleward flow of air on East coasts of continents
3.6.4. Air Mass formation and Precipitation:
Air mass is an extremely large body of air in the atmosphere whose properties –
temperature, humidity and lapse rate, which is the decrease of atmospheric temperature
with height, are largely uniform over an area which can be several hundred kilometers
across the surface of the earth.
Climate science defines air mass as a relatively huge bulk of air that is distinctive by
its homogeneity of temperature and moisture content.
Another definition is “An air mass is a large body of air with generally uniform
temperature and humidity”.
The area over which an air mass originates is what provides it’s characteristics.
The longer the air mass stays over its source region, the more likely it will acquire the
properties of the surface below. As such, air masses are associated with high pressure
systems.
Two different air masses can be separated and the line of distinction is called a front. It
is along with these fronts that weather formation occurs.
 Air masses are slowly pushed along by high-level winds, when an air mass moves over
a new region, it shares its temperature and humidity with that region.
So the temperature and humidity of a particular location depends partly on the
characteristics of the air mass that sits over it.
Storms arise if the air mass and the region it moves over have different characteristics.
For example, when a colder air mass moves over warmer ground, the bottom layer of air
is heated. That air rises, forming clouds, rain, and sometimes thunderstorms.
When a warmer air mass travels over colder ground, the bottom layer of air cools and,
because of its high density, is trapped near the ground.
In general, cold air masses tend to flow toward the equator and warm air masses tend to
flow toward the poles.
This brings heat to cold areas and cools down areas that are warm.
It is one of the many processes that act towards balancing out the planet’s temperatures.
Formation of Air Masses:
Differences in air pressure are caused by unequal heating of earths surface. Hot air
rises and cool air sinks.
Air Masses are most common in the tropics, subtropics, and high latitudes.
The zones from which air masses grow are called “source regions.” These are
generally tracts of ocean, desert or snow-covered plains.
The large surfaces with uniform temperatures and humidity, where air masses
originate are called source regions.
Uneven warming and cooling of the earth’s surface by the Sun gives rise to air
masses.
Ideal source regions are areas of High Pressure.
Map showing position of various Air masses
Cold Front:

A cold front forms when a cold air mass is actively underriding a warm air mass. As a cold
front advances, the warm air ahead of it is forced upward. This displacement often creates
cloudiness and relatively heavy precipitation along and immediately behind the ground level
position of the front.
 Because of friction with the ground, the advance of the lower portion of a cold air mass is
slowed relative to the upper portion. As a result, a cold front tends to become steeper as it
moves forward and usually develops a protruding “nose” a few hundred meters above the
ground.
The average cold front is twice as steep as the average warm front. Moreover, cold fronts
normally move faster than warm fronts because the dense, cold air mass easily displaces
the lighter, warm air.
This combination of steeper slope and faster advance leads to rapid lifting and adiabatic
cooling of the warm air ahead of the cold front. The rapid lifting often makes the warm air
very unstable, and the result is blustery and violent weather along the cold front.
Vertically developed clouds, such as cumulonimbus clouds, are common, with
considerable turbulence and showery precipitation.
Both clouds and precipitation tend to be concentrated along and immediately behind the
ground-level position of the front. Precipitation is usually of higher intensity but shorter
duration than that associated with a warm front
Warm Front:

A warm front forms when a warm air mass is actively overriding a cold air mass. As warm air
rises above cooler air, widespread cloudiness and precipitation develop along and in advance
of the ground-level position of the front. Higher and less dense clouds are often dozens
or hundreds of kilometers ahead of the ground-level position of the front.
The slope of a typical warm front is more gentle than that of a cold front. As the warm air
pushes against and rises over the retreating cold air, it cools adiabatically, usually resulting in
clouds and precipitation.
3.7. Energy Resources:

Almost all the developmental activities of modern society are directly or
indirectly dependent upon energy.
Energy consumption of a nation is usually considered as an index of its
development.
There is clear difference in per capita energy use between the developed and the
developing nations.
Utilization of energy probably first started when primitive man learnt to use fire
which produced heat and the early man used it for cooking and heating purposes.
Wind and hydropower have also been in use for the traditional society. The
invention of steam engines replaced the burning of wood by coal and coal was
later replaced to a great extent by oil.
3.7.1. Growing Energy Needs
Modern society heavily relies upon various forms of energy.
With growing populations, industrialization and other developmental sectors
demands for energy is increasing world over.

The fossil fuels like
coal, oil and natural
gas supply about 95%
of the commercial
energy in the world.
 Our changing life style
and quest for a more and
more luxurious life has
further increased the
demand of energy.
Increasing numbers of
electric gadgets in our
homes and rising number
of cars in our localities
demand increased
amounts of energy with
every passing day.
 The consumption and
demand of energy is much
higher in developed
countries. Countries like
U.S.A. and Canada
constitute only 5% of the
world’s population but
consume 25% of global
energy resources. Energy
consumption of a single
person in these countries
is about 300 GJ (Giga
Joules) per year.
 Whereas an average man in a poor country like Bhutan, Nepal or Ethiopia consumes less
than 1 GJ in a year. So a person in a rich country consumes almost as much energy in a
single day as one person does in a whole year in a poor country. This clearly depicts that
our modernized way of life needs much more energy.
 It indicates very high
demands of energy in the
world in future as the
world as a whole is shifting
from a simple way of life
to a modern and
sophisticated way of life.
Thus, there is very high
pressure on the existing
conventional sources of
energy. But, unfortunately,
these sources of energy are
not going to last forever.
Worlds Growing Energy Needs
3.7.2. Growing Energy Needs ( Energy Scenario in India)
(A) Energy Import
India, though rich in coal and abundantly endowed with renewable energy in
the form of hydro, wind, solar and bio-energy, has very small hydrocarbon
reserves.
India is a net importer of energy, more than 25% of primary energy needs
being met through imports mainly in the form of natural gas and crude oil.

(B) Energy Production Pattern
Coal and oil account for 54% and 34% respectively, with natural gas, hydro,
solar and nuclear contributing to the balance.
Nearly 62% of power generation is from coal-fi red thermal power plants and
70% of the coal produced every year in India has been used for thermal power
generation.
 Energy Distribution in India

(C) Distribution of Primary Commercial Energy Resources
The distribution is non-uniform. The northern and north-eastern regions
account for 70% of the total hydro potential, whereas the eastern region
accounts for about 70% of the total coal reserves in India.
The southern region has most of the lignite deposits in the country.
(D) Energy-Consumption Pattern
The industrial sector consumes about 52% of commercial energy production.
The energy consumption per unit of GDP (energy intensity) is one of the
highest in comparison to other developed and developing countries. Thus,
there is a huge scope for energy conservation in India.
(E) Future
The long-term availability of energy from sources that are affordable, accessible
and environmentally friendly will govern the future economic growth in India.

(F) Over-exploitation of Energy Resource in India
Power demand in India touched an all-time high of 99,027 MW recently, a year-
on-year growth of over 16%.
In our country, economic growth is very fast which is responsible for the
growing energy demands of the country.
India’s demand for energy is set to increase to as much as 415,000 MW by 2020
at an average GDP growth rate of 8% per year as per the forecast from
Mckinsey and company in 2008.
(F) Over-exploitation of Energy Resource in India
To meet this energy requirement, the country has to overexploit all its energy
resources. Presently the power needs of the country are primarily met by
thermal power stations (about 60%), followed by hydro, wind and nuclear
power stations.
India is experiencing shortages in the production of domestic coal. Many of
the thermal power stations, including NTPC, faced critical coal stock levels
and had to cut down their production levels.
The obvious result was power cut. In 2008–09 due to non-availability of
power, India Inc. has supposedly lost `43,205 crore as pera study.
The coal reserves of India may get exhausted by 2040 at the current rate of
coal consumption. India may have to depend entirely on coal imports.
(H) Problems due to Over-exploitation of Energy
In the US, nonrenewable fossil fuels provide 92% of the energy used. The US
has 3% of the world’s oil and petroleum resources, but consumes 25% of the
crude oil extracted in the world.
US citizens also waste tremendous amount of energy. Higher consumption of
energy resources means larger emissions of greenhouse gases which lead to
global warming and consequent problems.
Many developing countries are striving to reach the level of prosperity of the
US. It has been estimated that if world starts consuming at the same rate as the
US, the world could run out of fossil fuels in a few years.
Problems due to over-exploitation of energy resources
3.7.3. Sources of Energy
A source of energy is a substance or means that can provide adequate amount of energy
in a usable form over a long period of time. These sources can be of two types:
A. Non-renewable Energy Resources
Energy sources which have accumulated in nature over a long span of time and
cannot be quickly replenished when exhausted e.g. coal, petroleum, natural gas
and nuclear fuels like uranium and thorium.
They are also known as conventional sources of energy
B. Renewable Energy Resources
Energy Sources which can generate energy continuously in nature and are
inexhaustible or regenerable e.g. wood, solar energy, wind energy, tidal energy,
hydropower, biomass energy, bio-fuels, geo-thermal energy and hydrogen.
They are also known as non-conventional sources of energy and they can be
used again and again in an endless manner.
Important Energy Sources
Differences between conventional and nonconventional sources of energies
A. Non-Renewable Energy Resources
i. Fossil Fuels:
Fossil fuels like coal, petroleum and natural gas are the major sources of energy in
the present world. They are used as fuels and are nonrenewable.
These were formed by the decomposition of the remains of plants and animals buried
under the earth millions of years ago.
Nuclear energy is another form which is very effective but has also its own demerits.
a. Coal:
Coal is defined as stratified rock, consisting of organic matter of fuel value
derived from the partial decay and alteration of accumulated plant materials by
the action of heat and pressure over millions of years.
India has about 5% of world’s coal though Indian coal is not very good in
terms of heat capacity.
 Coal is of the following four types:

Major coal fields in India are Raniganj, Jharia, Bokaro, Singrauli, and
Godavari valley.
On burning coal causes serious environmental pollution including release
of carbon dioxide a major green house gas, SO2, NOx, Ash, and
Particulate matter.
b. Petroleum:
It is the most important energy source in the world.
There are 13 countries in the world having 67% of the petroleum reserves
which together form the OPEC (Organization of Petroleum exporting
countries). About 1/4th of the oil reserves are in Saudi Arabia.
Crude petroleum is a complex mixture of alkane hydrocarbons. Hence
it has to be purified and refined by the process of fractional distillation,
during whi