Unit 1 Environmental Studies Natural Resources and assosiated Problems.pdf

Full Transcript

CHE110: Environmental Studies
Environment (French word: Environer ) is the surrounding
things. It includes living things and natural forces. The
environment of living things provides conditions for
development and growth, also causes danger and damage.

Environment consists of the interactions among plants,
animals, soil, water, temperature, light, and other living and
non-living things.
Environment

Environment is what surrounds us !!
It is the sum total of all social, economical , biological , physical and
chemical factors which constitute the surroundings of humans, who
are both the creators and moulders of the environment.
Environment is of two types:

Natural Environment
Components such as air, water, soil, land, forest, wildlife, flora ,
fauna, etc. constitute the Natural Environment

Man - Made Environment
Alteration of the natural environment to serve specific uses by
the human beings is termed as Anthropogenic Environment.
For eg agricultural field is an anthropogenic environment and so
are the gardens and aquaculture farms.
Realms of the earth :There are four realms of the Earth :
Lithosphere, Atmosphere, Hydrosphere, Biosphere

Fig. Concept of Environment: air, water, land, living organisms
and materials surrounding us and their interactions
together constitute our environment
Types of Environment (Realms of the Earth)

Natural Environment Anthropogenic Environment
(an environment that is created
by humans)
Lithosphere (the solid, outer part of the Earth.)
Hydrosphere (the total amount of water on a
planet.)
Atmosphere (a layer or a set of layers of gases
surrounding a planet or other material body, that is
held in place by the gravity of that body.)
Biosphere (The biosphere is a global ecosystem
composed of living organisms (biota) and the
abiotic (non living) factors from which they derive
energy and nutrients.)
Components of Environment

There are two main components of Environment

Biotic Components(all living things)

Abiotic Components(Non living things)
Physical rain, humidity, temperature
Environment: etc.

Chemical Organic, inorganic compounds,
water acid, etc.
Environment:
 Biotic Components of Environment
Producers (or autotrophs)

Green plants and some bacteria which manufacture their own food.

Consumers (or heterotrophs)

Animals which obtain their food from producers
Primary consumers
Secondary consumers
Tertiary consumers

Decomposers

Bacteria and fungi that decompose dead
organic matter and convert it into
simpler parts
Abiotic Components(All non living things)
Environmental Science
It is an interdisciplinary academic field that integrates physical and
biological sciences to address the environmental problems.
Environmental Engineering
It is the application of science and engineering principles to improve
the quality of environment to provide healthy living conditions.
Environmental Studies
It is a broad interdisciplinary field of study which studies the
interaction of human beings with the environment.
Biotic Components
Multidisciplinary nature of Environmental Studies
Environmental Studies is a multidisciplinary subject that includes all
other disciplines such as Arts, commerce, climatology, geography and
other disciplines.
Fig. Multidisciplinary nature of Environmental studies
Importance of Environmental Studies
 To understand current environmental problems
 Helps to maintain ecological balance
 Provides basic knowledge of environment and related
issues
 Helps to achieve sustainable development & understand
the relationship between development & environment
 Educate people regarding our duties
 Environmental management
 Relates environment with economy
 Aims to protect biodiversity
 Agriculture and design of sustainable products
 information related to population explosion, growth &
development
 Scope of Environmental Studies

Environmental Management

Research and Ecosystem
Development Structure and
Function

Environmental Pollution Control Natural resource
conservation
Scope of Environmental Studies
 Ecosystem Structure & Function
 Ecology and biodiversity
 Natural Resource Conservation
 Environmental Pollution Control
 Environmental Management: CPCB, SPCB
 Industry
 Research & Development
 Social development: NGOs
 Environmental Journalism
 Environmentalist
 Green Advocacy
 Green Marketing
 Sustainable Development

The term sustainable development refers to the
development that meets the needs of the present
without compromising the ability of the future
generations to meet their own needs.
 Key aspects of sustainable development

Proper distribution of renewable and non-renewable
resources is the key of the concept of sustainable
development. And it can be achieve by the use of
following points.
Inter-generational equity:
The principle of intergenerational equity states that every
generation holds the Earth in common with members of the
present generation and with other generations, past and
future.
The principle is the foundation of sustainable development
Intra-generational equity:
Intra-generational equity deals with the
distribution of resources between the
members of the same generation.
Measures for sustainable
development
Implementing effective planning for
population control
Using effective/appropriate Technology:

“Design with Nature” Concept
Reduce, Reuse, and Recycle (3R’s)
Approach:
9 R’s of Waste management/Circular Economy
12 R’s Circular Economy
 Promoting Environmental
Education
and
Awareness:
 Resource Utilization as Per Carrying Capacity

Carrying Capacity:

Carrying capacity of a region/system could be described broadly as number of
individuals of a species that it can sustain. In case of human beings, it is rather a
complex situation, wherein the region/system has not only to bear the load of his basic
needs but also all other associated activities including industrial/developmental
projects which has direct impact on limited natural base and environmental quality.
The carrying capacity can be divided into two parts

(a) Supporting capacity (b) Assimilative capacity
 Supportive Capacity refers to capacity of a
region/system provides an assessment of the
stock of available resources with their
regenerative capacity on natural/sustainable
basis.
Assimilative capacity refers to the ability of
the environment or a portion of the environment
(such as a stream, lake, air mass, or soil layer)
to carry waste material without adverse effects
on the environment or on users of its resources.
Pollution occurs only when the assimilative
capacity is exceeded.
The political process
1992: Agenda 21 (Rio)

2002: World Summit on Sustainable
Development

2012: The Future we Want (Rio+20)

2015: Sustainable Development Goals
The Sustainable Development Goals (SDGs) or Global Goals are a collection of 17 interlinked
global goals designed to be a "blueprint to achieve a better and more sustainable future for all“.
The SDGs were set up in 2015 by the United Nations General Assembly (UN-GA) and are
intended to be achieved by the year 2030. They are included in a UN-GA Resolution called the
2030 Agenda or what is colloquially known as Agenda 2030
https://sdgs.un.org/goals
 17 goals under the Sustainable
Development Goals

1.End poverty in all its forms everywhere
2.End hunger, achieve food security and improved nutrition
and promote sustainable agriculture
3.Ensure healthy lives and promote well being for all at all
stages
4.Ensure inclusive and equitable quality education and
promote lifelong learning opportunities for all
5.Achieve gender equality and empower all women and girls
6.Ensure availability and sustainable management of water
and sanitation for all
7.Ensure access to affordable, reliable, sustainable and
modern energy for all
 17 goals under the Sustainable
Development Goals

8. Promote sustained, inclusive and sustainable economic
growth, full and productive employment and decent work for
all
9. Built resilient infrastructure, promote inclusive and
sustainable industrialization and foster innovation
10. Reduce inequalities within and among countries
11. Make cities and human settlements inclusive, safe,
resilient and sustainable
12. Ensure sustainable consumption and production pattern
13. Take urgent actions to combat climate change and its
impact
 17 goals under the Sustainable
Development Goals

14. Conserve and sustainably use the oceans, seas and marine
resources
15. Protect, restore and promote sustainable use of terrestrial
ecosystems, sustainably managed forests, combat
desertification and halt and reverse land degradation and halt
biodiversity loss
16. Promote peaceful and inclusive societies for sustainable
development, provide access to justice for all and build effective,
accountable and inclusive institutions at all levels
17. Strengthen the means of implementation and revitalize the
global partnership for sustainable development
https://dashboards.sdgindex.org/rankings
Using effective planning for regeneration
of natural resources:
Improving quality of life including social,
cultural and economic dimensions
Fig. Multidimensional model for sustainable
development
Measures for Sustainable Development(Summary)

Effective planning for population control

Reducing per capita demand of natural resources

Using efficient technological devices

Following the 5Rs (Refuse. Reduce, Reuse, Repair and
Recycling) approach

Promoting environmental awareness through education

Effective planning for regeneration of natural resources
Problems of Sustainable Development

Disagreements between stakeholders
Ex- Problem between different communities(Development,
economic growth )

Uncertainty
Ex- Global environmental issue.

Consumption and life style
Ex- Comparison between developed and undeveloped
countries.

Arguments over cause and responsibility
Ex-Pollution, Global warming etc.

https://www.youtube.com/watch?v=eEFwaQej_0E
Natural Resources
Natural resources are the substances which are inherent to earth and
obtained from nature and utilized to create products and services which
are useful for human beings. Forests, water, air, soil , etc. are natural
resources.
 Classification of Natural Resources
Resources
 Renewable Resources
 Non Renewable Resources
 Renewable and Non Renewable Natural
Resources
The resources that can be harvested continuously with proper
planning and management are called renewable resources.
Example: plants, animals, solar energy , wind energy, etc.
Non Renewable resources are natural resources which are
limited in supply and cannot be replenished by natural means.
Once exhausted, they have very little chance of recovery or
resynthesis. Coal, minerals, petroleum, etc. are Non Renewable
resources.
 Forest Resources

A forest, a biotic community with predominance of trees is
an important Renewable natural resource.
It is highly complex, changing environment made up of a
living and non living things. Living things include trees,
shrubs, wildlife etc. and non-living things include water,
nutrients, rocks, sunlight and air.
 Forest Resources
The word forest is derived from a Latin word “Fores” means
Outside

Forests are the dominant terrestrial ecosystem of Earth, and are
distributed across the globe.

Forests account for 75% of the gross primary productivity of
the Earth's biosphere, and contain 80% of the Earth's plant
biomass

Forest are one of the most important natural resources of the
earth.

Tree forests cover approximately 9.4 percent of the Earth's
surface (or 30 percent of total land area i.e., Approximately
1/3rd of the earth’s total land area ).
 Forest Types
Types of forest on basis of tree density

1. Very dense – above 70%

2. Moderately dense – 41 – 70%

3. Open forest – 10 – 40%
 As per Indian
state of forest
2021. India has
7,13,789 square
kilometres,
21.71% of the
country’s
geographical
area, an increase
from 21.67% in
2019.

Source: https://fsi.nic.in/isfr-2021/chapter-2.pdf
 Benefits of Forests
Protective Function
Forest Provide protection against Soil erosion, Droughts, floods, noise,
radiations

Productive Function
Forest Provide various products like, gum resins, medicines, Katha,
honey, pulp, bamboo, timber, and fruits

Regulative Function
The Forest regulates the level of Oxygen and carbon dioxide in
atmosphere. The forests also help in regulating temperature conditions

Accessory Function
Forest provides aesthetics, habitat to various flora and fauna besides that
it also has an recreational value
 Over-exploitation of Forests
Deforestation

The permanent
destruction of forest is
called deforestation

Forest are exploited since
early times for humans to
meet human demand
 Causes of Deforestation
Fuel requirement
Raw material for industrial
use
Development projects
Expansion of cities
Construction of dams,
canal & highways
Growing food needs
Overgrazing
Shifting Cultivation
Forest fire
 Major developmental Process resulting in Forest
losses

Source: https://www.indiatoday.in/diu/story/india-forests-a-tale-of-growth-loss-and-revival-2429324-
2023-08-3
 State wise Details of forest diversion among Indian states and union
territories

Source: https://www.indiatoday.in/diu/story/india-forests-a-tale-of-growth-loss-and-revival-2429324-
2023-08-3
Other causes
Mining:
River valley projects
Natural forces

64
 Effects of Deforestation

Threatens the existence of wildlife
Biodiversity and genetic diversity
loss
Effect of hydrological cycle
Soil erosion
Land slides on higher altitudes
Air pollution and global warming
Other consequences

Loss of habitat
Inc. intensity and frequency of flood
Land degradation
Loss of forest products
Change in climatic condition
Siltation of rivers and lakes
Loss of revenue
Change in water cycle
Reduced rainfall
Expansion of deserts

66
 Afforestation
“conversion of bare or cultivated land into forest”

67
 Afforestation
The conservation measure against the deforestation
is afforestation. The development of forest by
planting trees on waste land is called afforestation
The main objective of afforestation:
To control the deforestation
To prevent soil erosion
To regulate rainfall and maintain temperature
To control atmospheric condition by keeping it clean
To promote planned uses of wasteland
To Protect forest ecosystem and to get benefits of
forest products. 68
 Initiative/policies

National Mission for a Green India or the commonly called Green India
Mission (GIM)- launched in February, 2014 focus on Enhancing quality of forest
cover and improving ecosystem services from 4.9 million hectares (mha) of
predominantly forest lands, including 1.5 mha of moderately dense forest cover, 3 mha of
open forest cover, 0.4 mha of degraded grass lands.

“National Afforestation Programme (NAP)” for regeneration of degraded forests
and adjoining areas through people’s participation. The scheme is being implemented
through a decentralized mechanism of State Forest Development Agency (SFDA) at State
level, Forest Development Agency (FDA) at Forest Division level and Joint Forest
Management Committees (JFMCs) at village level. The Budget allocation for the current
financial year under NAP is Rs. 100 crore.
Free Seedling Distribution
Jharkhand topped the compensatory afforestation list by planting compensating trees on
almost 1.5 lakh hectares of land. Rajasthan planted on one lakh hectares. Other states like
Karnataka were a little behind, making commendable efforts to boost their forest cover. States
like Punjab and Bihar have achieved or maintained a balance between forest diversion and
compensatory afforestation. (Under Compensatory Afforestation Fund Act, 2016).
Water Resources
Distribution of Water
Water used by us in two forms:
i. Water withdrawal
ii. Water consumption
73
 Sources of Fresh water

1. Surface water

2. Frozen water

3. Ground water

4. Rain water
Surface water:
Surface water is water in a river, lake, ponds or fresh water
wetland. Surface water is naturally replenished by
precipitation and naturally lost through discharge to the
oceans, evaporation, and sub-surface seepage.
Ground Water:
Sub-surface water, or groundwater, is fresh water located
in the pore space of soil and rocks. It is also water that is
flowing within aquifers below the water table.
Aquifer: A layer of sediment/rock that is highly permeable
and contain water.
Layer of sand and gravel: Good aquifers
Clay and crystalline rocks (e.g. Granite): Not good aquifers
 Overutilization of water and its effect
Overutilization of water means extraction/consumption above the
natural recharge rate of water sources.

Effects:
Subsidence: aquifer got compact (due to more withdrawal and
less recharge) known as ground subsidence
Lowering of water table
 Water logging
Water pollution
Water shortage
 Conflicts over Water
Nile Water Conflict: Egypt vs. Ethiopia,
Brahmaputra Water Conflict: China, India,
Bangladesh etc.
Indus river conflict: India & Pakistan.
Inter-state disputes (e.g., Tamil Nadu and
Karnataka over Caveri water)
Industries vs. Communities (Coca-Cola
Beaverage company in Kerala.
80
Brahmaputra Water Conflict: China,
India, Bangladesh etc.
Indus river conflict: India & Pakistan
Source: https://www.civilsdaily.com/burning-issue-groundwater-depletion-in-india/
Sutlej Yamuna Link Canal Conflict
Inter-state disputes (e.g., Tamil Nadu and Karnataka over Caveri water)
 Water Stress versus Water Scarcity

Water scarcity is defined as the point at which the aggregate impact of all users
impinges on the supply or quality of water under prevailing institutional
arrangements to the extent that the demand by all sectors, including the
environment, cannot be satisfied fully.
Water scarcity is a relative concept and can occur at any level of supply or demand.
Scarcity may be a social construct (a product of affluence, expectations and
customary behaviour) or the consequence of altered supply patterns - stemming
from climate change for example.
Hydrologists typically assess scarcity by looking at the population-water equation.
An area is experiencing water stress when annual water supplies drop below 1,700
m3 per person. When annual water supplies drop below 1,000 m3 per person, the
population faces water scarcity, and below 500 cubic metres "absolute scarcity".

Water stress occurs when the demand for water exceeds the available amount
during a certain period or when poor quality restricts its use. Water stress causes
deterioration of fresh water resources in terms of quantity (aquifer over-
exploitation, dry rivers, etc.)
Water stress = Ratio of water use versus water availability
Water Scarcity can be:

1.Physical water scarcity is where there is not enough water to
meet all demands, including that needed for ecosystems to
function effectively.
Ex. Arid areas like Central and West Asia, North Africa often
suffer from physical water scarcity.

2. Economic water scarcity is caused by a lack of investment
in infrastructure or technology to draw water from rivers,
aquifers, or other water sources, or insufficient human capacity
to satisfy the demand for water.
Ex. Much of Sub-Saharan Africa has economic water scarcity.
Water Scarcity : Facts
Around 700 million people in 43 countries suffer today from
water scarcity.
By 2025, 1.8 billion people will be living in countries or regions
with absolute water scarcity, and two-thirds of the world's
population could be living under water stressed conditions.
With the existing climate change scenario, almost half the
world's population will be living in areas of high water stress by
2030, including between 75 million and 250 million people in
Africa. In addition, water scarcity in some arid and semi-arid
places will displace between 24 million and 700 million people.
Sub-Saharan Africa has the largest number of water-stressed
countries of any region.
Water Stress
Water Stress
 Solutions to Water Crisis
 Reduce demand.
 Adopt agriculture practices that require less water.
 Reduce industrial consumption through recycling, reuse and
new water-efficient technologies.
 Rainwater harvesting.
 Retain water on land as long as possible through check dams
and contour bunds allowing it to percolate into the ground.
 Implement rain water harvesting in urban and rural areas
 Restore traditional system of ponds and lakes.
 Adopt fairer policies
 National River Conservation Plan launched in 1995
 The National Water Mission (NWM) launched in 2010
 National water policy, 1987 (Amended in 2002 and 2012)
 River Rejuvenation Plan
93
 Water harvesting
Water harvesting is collecting and storing rain
water for future use.
The common methods of water harvesting are :-

i) Digging pits, ponds, lakes etc.
ii) Building small earthen dams or concrete
check dam.
iv) Construction of reservoirs.
v) Construction of rooftop collecting units in
houses.
94
Advantages of underground storage of water

i) It does not evaporate easily.
ii) It spreads out and recharges wells.
iii) It provides moisture for irrigation of crops.
iv) It does not get polluted easily.
v) It does not provide breeding ground for
mosquitoes and houseflies.

95
Common Methods of Urban Rainwater Harvesting
Some of the most familiar methodologies of urban rainwater
harvesting and management are –
1. Surface Runoff Harvesting
2. Rooftop Rainwater Harvesting
3. Recharge Pits
Rainwater Harvesting as State and Central Government Policy
More or less all states in India, through various legislative decisions, have made rainwater harvesting
mandatory in government institutions, commercial complexes, and residential high-rises. Some of these
laws have already come into effect, and others are soon to follow.
The Central Ministry for Drinking Water and Sanitation, in association with the Central Ground Water
Board, and a battery of groundwater scientists and experts, has also prepared a conceptual document
called the ‘Master Plan for Artificial Recharge to Ground Water in India’.
The master plan, related to rainwater harvesting and artificial recharge of groundwater, envisages the
construction of about 23 lakh rainwater harvesting structures in rural areas, and close to 88 lakh
artificial recharge and rainwater harvesting installations in urban centers.
Different methods of water harvesting

97
RAINWATER HARVESTING

98
Land resources
“Land resources include all those features and processes of
the land, which can, in some way, be used to fulfill certain
human needs”.
“The solid portion of the earth’s surface”.
The science dealing with land is known as pedology.
Land resources
Soil is defined as a natural body consisting of layers (soil horizons) that are composed of
weathered mineral materials, organic material, air and water.

https://www.fao.org/soils
  Soil Formation:

 Soil Profile: Horizons O, A, E, B, C

 Function of soil:
 nutrient cycle
agriculture
water storage
emission of gases
degrade pollutant
clay
foundation

* C Horizon is also known as saprolite
Function of soil

Various functions of soil are

They have a significant role in nutrient cycles.

They are the basis of agricultural production.

They store water and regulate water supplies.

They regulate the emissions of trace gases.

They degrade pollutants and filter ground water

103
World Land resources and its Usage

104
 Land Degradation
Land degradation is defined as “the persistent reduction of
the production capacity of a land, which may be manifest
through any combination of several interrelated processes, such
as soil erosion, deterioration of soil nutrients, loss of
biodiversity, deforestation or declining vegetative health”

Globally, about 25 percent of the total land area has been degraded.
When land is degraded, soil carbon and nitrous oxide is released
into the atmosphere, making land degradation one of the most
important contributors to climate change. Scientists recently warned
that 24 billion tons of fertile soil was being lost per year, largely due
to unsustainable agriculture practices. If this trend continues, 95
percent of the Earth’s land areas could become degraded by 2050.
Land Degradation
 Land Degradation
Causes
– Natural causes
Heavy rainfall
High speed winds
Natural disasters: earthquake,
landslide, flood, drought.
Expansion of desert
 Anthropogenic causes
-Mining
-Urbanization
-Deforestation
-Overgrazing
-Water logging Mining Deforestation
-Construction of dams
-Extensive use of fertilizers
-Dumping of industrial and
municipal wastes

Urbanization Overgrazing Excess use of Agrochemicals
Land degradation :Indian Scenario
Soil Erosion

Soil erosion is removal of top soil from its resting place by
various physical agencies like wind and water. It can be
defined as “the detachment and transport of the fertile
layer of soil by water or air.” It is also known as the
creeping death of land.
 Soil Erosion
Soil erosion may be defined as the detachment and removal
of the top soil layers from soil mass
Types
– Normal erosion or geologic erosion
– Accelerated or Anthropogenic erosion
Causes
Climatic agents
Water induced erosion
– Splash erosion
– Sheet erosion
– Rill/Gully erosion
– Stream bank erosion
Wind induced erosion
– Suspension
– Saltation
– Surface creep
– Biotic agents
Causes of Soil Erosion

Large scale deforestation

Floods

Overgrazing

Large Violent Winds

Improper agricultural techniques
Effects of soil Erosion

115
 Method of controlling soil Erosion

1. Conservational till farming: no till farming
2. Contour farming
3. Terracing
4. Strip cropping
5. Alley cropping: Agroforestry
6. Wind breaks or shelterbelts
7. Stubble-mulching
8. Afforestation
9. Control overgrazing
10.Check dam
11.Equitable use of water sources
 Soil Erosion

Control
– Conservational till farming.
– Stubble mulching.
– Contour farming.
– Contour bunding.
– Construction of check dams.
– Terracing
– Strip cropping.
– Alley cropping (Agro-forestry)
– Wind breaks.
– Afforestation
– Control overgrazing
– Equitable use of water sources
Conservational till farming: no till farming
Contour bunding & cultivation Vegetative bunds

Terracing Strip cropping
Alley cropping: Agroforestry
Wind breaks or shelterbelts
Wind breaks or shelterbelts
Stubble Mulching
Afforestation
 Check dam

A check dam is a small dam constructed across a drainage ditch or channel to
lower the velocity of flow

126
 International approach to conserve soil

World Soil Day (WSD) is held annually on 5 December as a means to
focus attention on the importance of healthy soil and to advocate for the
sustainable management of soil resources.

An international day to celebrate soil was recommended by the
International Union of Soil Sciences (IUSS) in 2002. Under the
leadership of the Kingdom of Thailand and within the framework of the
Global Soil Partnership, FAO has supported the formal establishment of
WSD as a global awareness raising platform. The FAO Conference
unanimously endorsed World Soil Day in June 2013 and requested its
official adoption at the 68th UN General Assembly. In December 2013, the
UN General Assembly responded by designating 5 December 2014 as the
first official World Soil Day.

Read out more about Global Soil partnership at
https://www.fao.org/global-soil-partnership/en/
 Desertification
Desertification is the process by which the biological productivity of
drylands is reduced due to natural or manmade activities
Or
the process by which fertile land becomes desert, typically as a result
of drought, deforestation, or inappropriate agriculture.

128
 Desertification
Types
– Moderate (10 - 25%)
– Severe (25 - 50%)
– Very severe (more than 50%)
Causes
Natural causes Anthropogenic causes

Very low rain fall
High salinity
Excessive evaporation
Deforestation
Vast difference in diurnal temperature
Topography related factor Overgrazing

Conversion of pasture into arable land

Excessive use of fertilizer
Cause:
Natural Factors:

Low Excessive
Rainfall Evaporation

Salinity Temperature

130
Anthropogenic Factors:

Mining Overgrazing

131
 Desertification
Effects
– Rapid soil erosion
– Poor soil quality
– Unfavorable climate
– Low water table, salty and hard water
– Economic and human cost
– Decreased productivity of land
– Expansion of desert
– Deposition of soil in water bodies
– Reduction of agricultural land in around river banks
 Desertification
Control
– Large scale plantation
– Sustainable agricultural practices
– Development of pasture land and controlling
overgrazing
– Development of water catchment
– Rainwater harvesting
Control:

134
 What is Energy?
“ capacity to do work”

In physics, energy is the quantitative property that must be transferred
to a body or physical system to perform work on the body, or to heat
it. Energy is a conserved quantity; the law of conservation of energy
states that energy can be converted in form, but not created or
destroyed.

SI unit of Energy is “Joule”

Energy resources refer to “all renewable and non-renewable energy
resources of both inorganic and organic origins discovered in the
earth’s crust in solid, liquid and gaseous form.”
 Earth Energy Balance
Earth Energy Balance
Renewable Sources of Energy Non Renewable
Sources of Energy

Solar Energy Coal

Wind Energy Natural Gas and Oil

Tidal Energy Nuclear Energy

Geothermal Energy

Biomass Based Energy
Energy Resources: Global dependencies
Energy Consumption
Power Sector at Glance: India

https://powermin.gov.in/en/content/power-sector-glance-all-india
Renewable Sources of Energy Non Renewable Sources of Energy

Solar Energy Coal

Wind Energy Natural Gas and Oil

Tidal Energy Nuclear Energy

Geothermal Energy

Biomass Based Energy

141
 Energy Crises
“An energy crisis is any
significant bottleneck in the
supply of energy resources to
an economy.
In literature, it often refers to
one of the energy sources used
at a certain time and place, in
particular those that supply
national electricity grids or
those used as fuel in Industrial
development and population
growth have led to a surge in
the global demand for energy
in recent years.”
 Reasons for Energy Crises

 Over reliance on non renewable energy resources.
 Overpopulation.
 Poor infrastructure/distribution system.
 Wastage/Lack of energy efficiency.
 Major Accidents and Natural Calamities
 Wars and Attacks
 Miscellaneous Factors
 Reasons for Energy Crises

 Over reliance on non renewable energy resources.
 Reasons for Energy Crises

 Per capita energy consumption/Overpopulation
 Production versus Consumption
 Reasons for Energy Crises
 Poor infrastructure/distribution system

World electricity transmission losses to percent of total generation by selected countries
and regions 2001 and 2013 Source: https://www.eia.gov/
 Reasons for Energy Crises
 Wars and Attacks

https://www.oilandgasiq.com/strategy-management-and-
https://www.nytimes.com/2019/09/14/world/middleeast/saudi- information/whitepapers/cyber-war-us-and-eu-oil-gas-
arabia-refineries-drone-attack.html under-attack-is-asia-n
 Reasons for Energy Crises
 Natural Calamities

Effect of natural disaster on energy transmission system

Damaged wind turbine due to wind storm
 Reasons for Energy Crises
 Miscellaneous Factors
 Effects Energy Crises

 Increase in fuel/resource demand
 Increase in fuel price
 Economic Slowdown
 Political Disturbances
 Effect on tourism and other activities
Headlines: Increase in fuel prize
 Move Towards Renewable Resources

Renewables use in total energy consumption

Source: https://www.sciencedirect.com/science/article/pii/S2211467X19300082
 Hydro-electric energy

The potential energy in the water stored in dams is converted into electrical energy by
releasing the water flow and rotating the turbine
Advantages
– Low operating and maintenance cost
– Non-polluting
– Reliable
– Flexible
– Safe
Disadvantages
– High setup cost
– Affects fish population
– Limited reservoirs
– Affected by draught
– Probable seismic activity
 S.No. Name of Plant River State
1. Koyna Hydro Electric Power plant Koyna Maharashtra
2. Hirakund Hydro Electric Power plant Mahanadi Odisha
3. Idukki Hydro Electric Power plant Periyar Kerala
4. Nagarjuna Hydro Electric Power plant Krishna Andhra Pradesh
5. Tehri Hydro Electric Power plant Bhagirathi Uttarakhand
6. Bhakra Nangal Hydro Electric Power plant Sutlej Himachal Pradesh
7. Sardar Sarovar Hydro Electric Power plant Narmada Gujarat
8. Nathpa Jhakri Hydro Electric Power plant Sutlej Himachal Pradesh
9. Srisailam Hydro Electric Power plant Krishna Andhra Pradesh
10. Indirasagar Hydro Electric Power plant Narmada Madhya Pradesh
11. Sharavathi Hydro Electric Power plant Sharavathi Karnataka
12. Dehar Hydro Electric Power plant Beas Himachal Pradesh
13. Kalinadi Hydro Electric Power plant Kalinadi Karnataka
14. Teesta Hydro Electric Power plant Teesta Sikkim
15. Baira-Siul Hydro Electric Power plant Baira Himachal Pradesh
16. Salal Hydro Electric Power plant Chenab Jammu and Kashmir
Andhra Pradesh, Orissa
17. Machkund Hydro Electric Power plant Machkund
18. Balimela Hydro Electric Power plant Sileru Odisha
19. Subarnarekha Hydro Electric Power plant Subarnarekha Jharkhand
20. Shivanasamudra Hydro Electric Power plant Kaveri Karnataka
21. Loktak Hydro Electric Power plant Leimtak Manipur
22. Rihand Hydro Electric Power plant Rihand Madhya Pradesh, Uttar Pradesh
23. Rangit Hydro Electric Power plant Rangit Sikkim
24. Bansagar Hydro Electric Power plant Sone Madhya Pradesh
25. Uri Hydro Electric Power plant Jhelum Jammu and Kashmir
 Solar energy
1 hour solar energy can be used for 1 year
Uses of solar energy
– Solar heating of home (sunspace)
– Solar water heating, solar cooker, solar furnace
– Solar desalination system
Photovoltaic energy: Silicon -> PV cells -> PV modules -> PV array
-> solar panel
Advantages
– Easy to install
– No pollution, no noise
– Can be installed anywhere
Disadvantages
– Doesn’t work when light is not available
– Requires energy storage device
– Low efficiency
– Damage easily

Solar power in India is a fast developing industry. The country's solar installed capacity reached 33.730 GW as of
31 December 2019. In 2015 the target was raised to 100 GW of solar capacity (including 40 GW from rooftop
solar) by 2022, targeting an investment of US$100 billion. As on Dec 2023 installed Solar capacity 73.31GW.
 Wind energy
One of the earliest renewable energy –
sail ships, windmills
India is the 4th largest producer of wind
energy (after China, US and Germany).
Advantages
– Unlimited, free, renewable resource
– Low maintenance cost
– No pollution
Disadvantages
– High setup cost
– Birds and bats get killed
– Noise and signal reception problem

India has the 4th largest installed capacity in wind power after China, U.S and Germany. The total installed capacity of wind
power in India as on March 2017 is around 32 GW. A recent study by National Institute of Wind Energy (NIWE) has shown wind
energy potential of 302 GW at 100 m hub-height in India. As on Dec 2023 installed wind energy capacity is 44.73GW.
 Tidal energy
Tidal power or tidal energy is a form of hydropower that
converts the energy obtained from tides into electricity.
To capture sufficient power from the tidal energy potential,
the height of high tide must be at least five meters (16 feet)
greater than low tide
Advantages
– Tides are more predictable than the wind and the sun
– Uses less area.
– No emission of gaseous or particulate pollutants
– longevity of equipment
Disadvantages
Types
– Electro-magnetic emission affects the aquatic life.  Tidal stream
generator  Dynamic tidal power
– High construction cost  Tidal barrage  Tidal lagoon

Ministry of New and Renewable Energy estimated that the country can produce 7000 MW of power in the Gulf of
Khambhat in Gujarat, 1200 MW of power in the Gulf of Kutch in Gujarat and about 100 MW of power in the Gangetic
delta of Sunderbans in West Bengal.
The largest facility is the Sihwa Lake Tidal Power Station in South Korea. China, France, England, Canada, and Russia
have much more potential to use this type of energy.
 Geo-thermal energy
The energy harnessed from the hot rocks
present inside the earth is called geothermal
energy.
Sometimes natural geysers or artificially drilled
holes can be used to released the water
vapour underneath the earth surface.
Advantages
– No pollutant emission
– Reliable source of renewable energy
– Less operating cost
– Less maintenance cost
Disadvantages
– Possibility of emissions of H2S, CO2, CH4 during
extraction
– High Investment Costs

In India, by the time, geothermal energy installed capacity is experimental however, the potential capacity is more than 10,000 MW. Following are the six most
promising geothermal energy sites in India −
1. Tattapani in Chhattisgarh
2. Puga in Jammu & Kashmir
3.Cambay Graben in Gujarat
4.Manikaran in Himachal Pradesh
5. Surajkund in Jharkhand
6. Chhumathang in Jammu & Kashmir
 Ocean-thermal energy
The energy available due to the difference in
temperature of water at the surface of tropical oceans
and deeper levels is called ocean-thermal energy.
Ocean thermal energy conversion, or OTEC, uses
ocean temperature differences from the surface to
depths lower than 1,000 meters, to extract energy.
A temperature difference of only 20°C can yield
usable energy.
The heat is used to vaporize ammonia (closed cycle)
and rotate the turbine sing the vapour.
Advantages
– Continuous source of energy
– No pollutant emission
– Output shows very little seasonal variation
Disadvantages
– Capital investment is very high
– High maintenance cost
– Low efficiency
– Pipes could damage coral reefs
The total OTEC potential around India is estimated as 180,000 MW, considering 40% of gross power for parasitic losses. However, the cost
estimates of ocean energy as against conventional energy is still being worked out, as the country is still in a nascent stage of development of the
technology and start generation. Chennai-based National Institute of Ocean Technology (NIOT) is setting up the world’s first self-powered
desalination plant using the technology of ocean thermal energy conversion (OTEC) in Kavaratti Island in Lakshadweep.
 Nuclear energy
History: Nuclear energy has been used to produce electricity for
decades. Nuclear fission was first experimented on by Enrico Fermi
in 1934. The idea to use nuclear energy to produce electricity was not
realized until 1951. A station near Arco, Idaho, was the first to
produce electricity from a nuclear reactor in that year. In the years
after, several countries were using nuclear energy to produce
electricity.
Types of nuclear reactions
– Fission: Splitting of large nucleus into smaller nuclei.
– Fusion: Joining of small nuclei into a large nucleus.
Elements used in nuclear energy production: Uranium,
Thorium, Plutonium
Advantages
– Less fuel offers more energy.
– The cost of nuclear fuel is only 20% of the cost of energy
generated.
– The production of electric energy is continuous (almost
90% of annual time).
Disadvantages
Currently, there are 450 nuclear reactors in operation in 30 countries
– Risk of unexpected event or nuclear accidents. around the world. One of the largest plants is situated in France, where
– Difficulty in the management of nuclear waste. about 70 percent of total electricity generation was derived from
– Nuclear plants have a limited life. nuclear sources in 2018. Most of those reactors are operating within a
few countries, namely, the United States, France, Japan, Russia and
Korea.
As of March 2018, India has 22 nuclear reactors in operation in 7 nuclear power plants, with a total installed capacity of 6,780 MW. Nuclear
power produced a total of 35 TWh and supplied 3.22% of Indian electricity in 2017.
 List of Nuclear Power Plants in India

S.No Name of the power station State Operator Total capacity

1. Tarapur Atomic Power Station Maharashtra NPCIL 1,400

2. Kakrapar Atomic Power Station Gujarat NPCIL 440

3. Kudankulam Nuclear Power Plant Tamil Nadu NPCIL 2,000

4. Kaiga Nuclear Power Plant Karnataka NPCIL 880

5. Madras Atomic Power Station Tamil Nadu NPCIL 440

6. Rajasthan Atomic Power Station Rajasthan NPCIL 1,180

7. Narora Atomic Power Station Uttar Pradesh NPCIL 440
Log burning is a simple way use biomass energy
Wood is the largest source of biomass energy. It can also be used in electricity production in wood-
based power stations.
Energy crop
An energy crop is a plant grown as a low-cost and low-maintenance harvest used to make
biofuels, such as bioethanol, or combusted for its energy content to generate electricity or
heat. Example: Jatropha, Sunflower etc.
Energy trapped inside biomass
Biofuels
Biodiesel
Biopetrol
Biogas
Bio-ethanol
Bio-methanol
 Biomass Energy in India

India has a potential of about 18 GW of energy
from Biomass. Currently, about 32% of total
primary energy used in India is derived from
Biomass. More than 70% of the country’s
population depends upon biomass for its energy
needs. India has ~5+ GW capacity biomass
powered plants: 83% are grid connected while
the remaining 17% are off-grid plants.

The leading states for biomass power projects
are Maharashtra, Uttar Pradesh and Karnataka
each one having more than 1 GW of Grid
interacted biomass power. Other states with
favorable policy and opportunities in Biomass
are Punjab and Bihar.
 Refuse Derived Fuel (RDF)
RDF consists largely of combustible components of such waste, as non
recyclable plastics , paper cardboard, labels etc.
These fractions are separated by different processing steps in order to produce a
homogeneous material which can be used as substitute for fossil fuels.

Dehradun based Indian Institute of Petroleum (IIP), a constituent laboratory of the Council
of Scientific and Industrial Research (CSIR) in 2014, developed a unique process of
converting plastic waste like polyethylene and polypropylene, both together accounting for 60
per cent of plastic waste, can be converted to either gasoline or diesel. The technology is
capable of converting 1 kg of plastic to 750 ml of automotive grade gasoline. Due to nearly nil
presence of Sulphur in the produced fuel, IIP’s plastic converted fuel is pure and meets the
Euro-III standards. IIP also stated that a vehicle using this fuel would be able to run for at
least two kilometres more per litre. The technology was developed by IIP after nearly a
decade of research in hope of commercialising it for industrial usage.
166
As of Dec 2023, Renewable energy sources, including large hydropower,
have a combined installed capacity of 180.79 GW.

The following is the installed capacity for Renewables:

Wind power: 44.73 GW
Solar Power: 73.31 GW
Biomass/Co-generation: 10.2 GW
Small Hydro Power: 4.98 GW
Waste To Energy: 0.58 GW
Large Hydro: 46.88 GW

India stands 4th globally in Renewable Energy Installed Capacity (including
Large Hydro), 4th in Wind Power capacity & 4th in Solar Power capacity (as
per REN21 Renewables 2022 Global Status Report).The country has set an
enhanced target at the COP26 of 500 GW of non-fossil fuel-based energy by
2030.
Limitations of Alternative Source of Energy

Most of the technologies involve high installation cost and
require maintenance.

The material that find application in designing and
manufacturing of device are not easily available. (Silicon
example)

Weather problem.

Geographical problem.
 Solutions

Move Towards Renewable Resources
Increasing Energy Efficiency
Buy Energy-Efficient Products
Lighting Controls
Energy Simulation
Perform Energy Audit
Common Stand on Climate Change
 Energy Conservation through individual
actions
Role of Individual in conservation of
energy and natural resource
Role of Individual in conservation
of energy and natural resource
Thanks