Difference between revisions of "Energy"

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 +
= Introduction =
 
   
 
   
= Scope of this document =
+
This is a resource document for teachers on the
 +
various topics of energy covered in high school. This contains
 +
resource and reference material for the teachers as well as
 +
classroom-based activities and discussions that the teacher can use
 +
to build conceptual clarity and understanding.
 +
 
 
   
 
   
The following note is a background document for
+
This resource contains sections on what does
teachers. It summarises the things we will need to know. This note is
+
energy mean, the relation between work done and energy, various forms
meant to be a ready reference for the teacher to develop the concepts
+
of mechanical energy and the units of measuring power. Further
in energy from Class 6 onwards to Class 10.
+
conversion between various forms of energy is explored. The resource
 +
also discusses renewable and non-renewable energy sources with a
 +
detailed discussion on atominc energy as well. Energy flow in the
 +
universe and eecosystem is also discussed to connect the living
 +
ecosystem to the sources of energy, particularluy solar energy.
 +
Energy storage and management are also discussed in this resource.  
 +
Where necessary, activities have been described in detail for the
 +
teacher to use in the classroom. The resource also points to
 +
additional web resources.
  
 
   
 
   
This document attempts to cover all the topics
+
'''E'''nergy is the basis of human
identified in the concept map. To plan the actual lessons, the
+
life. Every single aspect of human experience whether it be in the
teacher must use this in connection with the theme plan.
+
external world or what we do or what is done to us can be adequately
 +
described either as a transfer of energy in one form from one place
 +
to another or the transformation of energy from one form to another.
 +
What is the meaning of energy? How does one measure it? What are the
 +
various forms in which energy manifests itself? How is energy
 +
obtained and transformed from one form to the other? How can energy
 +
be conserved? How do the production and utilization of energy in its
 +
various forms affect our environment? What is the source of all
 +
energy? What kind of energy flows and conversions take place in the
 +
environment? These are some questions we will explore here.
  
 
   
 
   
 +
= Concept Map =
 +
 +
<br>
 +
<br>
  
 +
 +
[[Image:Energy%20for%20KOER_html_m5d4a74f5.jpg]]<br>
 +
<br>
  
 +
 +
<br>
 +
<br>
  
 
   
 
   
= Theme Plan =
+
= Work, Energy and Power =
                                               
+
{| border="1"
+
We often use the terms work in ordinary
|-
+
conversation. Further, we also say that energy is needed to do work.
|
+
We will explore the idea of work done, energy, power and energy
'''CLASS'''
+
conversions in this section.
  
 
   
 
   
|
+
Some of the key ideas to be covered in this
'''SUB-TOPIC'''
+
section are:
  
 
   
 
   
|
+
# Work has a physical meaning in relation to the force operating and this is linked to the concept of energy. Such work done can be measured in physical terms.
'''CONCEPT
+
# What do we mean when we say an object has energy? We are introduced to the idea of kinetic and potential energy.
DEVELOPMENT'''
+
# Effectivesness of doing work is called power; work, energy and power have units of measure.
 
+
 +
== Concept flow ==
 +
 +
=== What does work done mean? ===
 
   
 
   
|
+
We often use the terms work in ordinary
'''KNOWLEDGE
+
conversation. We say for example “This job requires a lot of work”.
OUTCOMES'''
+
What does ‘work’ really mean here? Further, we also say that
 +
energy is needed to do work. We will explore the idea of work done,
 +
energy, power and energy conversions in this section.
  
 
   
 
   
|
+
Work always involves some opposing forces. What
'''SKILL
+
do we mean by this? If we lift a box from the ground level and place
OUTCOMES'''
+
it on a high shelf, we feel tired after the job is completed; we feel
 +
that we have done some work. How is this done? Gravity pulls the
 +
box and hence we are doing work against this gravitational force.
 +
This is true for any type of work.
  
 
   
 
   
|
+
Suppose that instead of lifting the box, we push
'''ACTIVITIES'''
+
it across a rough floor. In this case, we are not working against
 +
the gravitational force-the box is at the same height throughout the
 +
movement. Instead, we are now working against the frictional force
 +
that exists between the moving the box and the floor.
  
 
   
 
   
|-
+
In physical terms, work done is
|
+
directly proportional to both the applied force and the distance
6
+
through which the force acts.
  
 
   
 
   
|
+
'''How do we measure work here?'''
Work
 
,measurement of work
 
  
 
   
 
   
|
+
We know that there is some cause, a force that
Work
+
results in a change in state of an object. When such a change in
is something done. Work always involves overcoming some opposing
+
state occurs, it often results in a change in energy of the object.
force; force does workand produces a change in energy. Work done
+
Is this waiter carrying a tray doing work?
is directly proportional to both the applied force and the
 
distance through which the force acts
 
  
 
   
 
   
|
+
When force acts over a period of time, there is an
They
+
impulse I = F x t = m(v – mu) is the change in momentum of the
will know that work is done on a body only when it is displaced
+
body. Let us now look at what happens when force acts on an object
 +
over a distance along the direction of the force. In we say work is
 +
done by a force if the force acts on an object over a distance and we
 +
say that the work done W = Force F x distance travelled along the
 +
direction of the force.
  
 
   
 
   
|
+
[[Image:Energy%20for%20KOER_html_m7d349003.png]]Notice
They
+
that the work done is the same in all the three cases above though
will learn to calculate the work done when a known force is
+
the force applied is different. Greater the angle of inclination,
applied on a body and the distance travelled is measured.
+
greater is the force needed.
  
 
   
 
   
|
+
Thus W = F x d if the distance travelled d is in
Activity
+
the same direction as the force. If the direction in which the object
1
+
is moving is at angle θ then the distance travelled in the direction
 +
of the force would be d Cos θ and the work done would be W = f x d
 +
Cosθ.
  
 
   
 
   
|-
+
[[Image:Energy%20for%20KOER_html_6f7bb14c.gif]]If
|
+
the force is acting perpendicular to the direction of the work done,
7
+
there is no work done. If you are carrying a heavy bag in your hand
 +
and walking, though you may feel tired, no work is done in the
 +
physical sense, because there is no energy change that has occurred
 +
for the bag.
  
 
   
 
   
|
+
Work done, is defined as a particular form of
Types
+
product of two vectors – force and displacement. Such a product is
of energy-Kinetic and potential
+
called the scalar product and the resulting quantity is a scalar. In
 +
the context of work done, this is easy to understand. You don’t do
 +
work in a particular direction – you just do work.
  
 
   
 
   
|
+
The unit of work done is joules. 1 J of work is
The
+
said to be done when a force of 1 N causes a displacement of 1 m.
energy that an object possesses by virtue of its motion is
 
Kinetic energy.The energy that an object possesses when it is
 
lifted to a height or it is put under strain is potential energy.
 
  
 
   
 
   
Potential
+
When work is done, it is done over a certain time.
energy is potential for energy.
+
The rate of doing work is defined as the power. Power is defined as
 +
(work done)/ time taken.
  
 
   
 
   
|
+
Power = work done/ time = force x displacement/
A
+
time = force x velocity
moving body possess Kinetic energy and the energy stored in a
 
body is potential energy
 
  
 
   
 
   
|
+
Its unit is Watt.
Observes
 
different situations in daily life when and where a body possess
 
kinetic energy and potential energy
 
  
 
   
 
   
|
+
=== Energy, types of energy-Kinetic and potential ===
Activity
 
2
 
 
 
 
   
 
   
|-
+
When an object is moved against a force, work is
|
+
done and energy is spent in the process. Thus we say “A person
8
+
must have a lot of energy to do a hard day’s work”. In fact one
 +
way to define energy is: Energy is the capacity to do work.
  
 
   
 
   
|
+
The word ‘energy’ is derived from the Greek
Different
+
'''''energia''''''''-en means ''''''''‘in’''''''''
forms of kinetic energy and potential energy
+
and''' '''''ergon'''''''', means
 +
''''''''work'''''.
  
 
   
 
   
|
+
[[Image:Energy%20for%20KOER_html_77958556.jpg]][[Image:Energy%20for%20KOER_html_4c924b2.jpg]]<br>
Kinetic
+
<br>
energy is there when there is motion. Object possesses potential
 
energy in different forms.
 
  
 
   
 
   
|
+
<br>
Identifies
+
<br>
Kinetic energy and potential energy in various forms
 
  
 
   
 
   
|
+
<br>
Observes
+
<br>
the different forms of energy in terms of kinetic energy and
 
potential energy
 
  
 
   
 
   
|
+
<br>
 +
<br>
  
 +
 +
<br>
 +
<br>
  
 
   
 
   
|-
+
<br>
|
+
<br>
9
 
  
 
   
 
   
|
+
Energy is defined for an object in a particular
 
+
state. When work has been done on an object, its energy changes. At
 +
a very basic level, there are two forms of energy – kinetic energy
 +
and potential energy.
  
 
   
 
   
|
+
For example, a block is lying at rest on a table.
Power
+
It is pushed and it acquires a uniform velocity. Now the block has
is the rate at which work is done or energy is used or supplied
+
acquired some energy (kinetic energy, as we will define shortly).
and therefore is calculated by dividing the work done or energy
+
While the cause of the change in the state was a force (the push), it
used or supplied in the process by the time taken by the process.
+
has resulted in the body acquiring a change in energy.
  
 
   
 
   
|
+
We can see that there are two ways of describing
Learns
+
this (and for that matter, any) process. One is to study the cause
that energy used to do a work varies from person to person and
+
(the force) and the other is to examine the change in energy.
varies for different activities. Understands the way machines
 
work.
 
  
 
   
 
   
|
+
'''Understanding Kinetic Energy'''
Uses
 
the unit of power in their daily life. Example in the electricity
 
bills.
 
  
 
   
 
   
|
+
If an object is moved from rest to a uniform
Chart
+
velocity, horizontally, it has acquired kinetic energy. Conversely,
of energy requirements for various activities
+
if an object is moving with a velocity ‘v’ and has to be stopped,
 +
work needs to be done. Let us understand this mathematically.
  
 
   
 
   
|}
+
Let us say an object of mass ‘m’ is moving
 +
with a velocity ‘v’ and is brought to rest by a retarding force
 +
over a distance ‘s’
  
 
+
 
+
The
                                                                                                   
+
acceleration = v<sup>2</sup>/ 2s
{| border="1"
 
|-
 
|
 
'''CLASS'''
 
  
 
   
 
   
|
+
The force required = m x a
'''SUB-TOPIC
 
'''
 
  
 
   
 
   
|
+
= m x v<sup>2</sup>/
'''CONCEPT
+
2s
DEVELOPMENT'''
 
  
 
   
 
   
|
+
Work done =
'''KNOWLEDGE
+
force x displacement
OUTCOMES'''
 
  
 
   
 
   
|
+
= (m x v<sup>2</sup>/
'''SKILL
+
2s) x s
OUTCOMES'''
 
  
 
   
 
   
|
+
= ½ m v<sup>2</sup>
'''ACTIVITIES'''
 
  
 
   
 
   
|-
+
This is the expression of the kinetic energy that
|
+
the object had.
10
 
  
 
   
 
   
|
+
If this object is a car and it was brought to rest
Fossil
+
by braking, the kinetic energy was lost as heat energy due to
fuels-formation and processing of coal and petroleum.
+
friction (braking) between the road and the car tires. The total
 +
energy remains conserved; it merely moves from one form to another.
  
 
   
 
   
|
+
All energy is due to
Fossil
+
motion and is kinetic energy. The energy that an object possesses
fuels are a result of processes that occur over a long time;
+
by virtue of its motion is Kinetic energy.
non-renewable. All fossil fuels are exhaustible.
 
  
 
   
 
   
|
+
[[Image:Energy%20for%20KOER_html_m23570b7e.gif]]'''Understanding
Fossil
+
Potential Energy'''
fuels are the result of decomposition of living matter. coal is a
 
fossil fuel which is obtained from dead plant matter which
 
consists primarily of carbon, hydrogen and oxygen and it can be
 
used with or without processing. Whereas petroleum is a fossil
 
fuel which is a mixture of hundreds of hydrocarbon compounds
 
together with small amounts of compounds of other elements and it
 
should be used only after processing.
 
  
 
   
 
   
|
+
If an object is lifted from the ground to a
Uses
+
certain height, work has been done in moving it and this is stored in
the fossil fuels judiciously.
+
the object as potential energy. If the object is dropped, it will
 +
fall to the ground with a velocity and will acquire kinetic energy.
  
 
   
 
   
|
+
* Potential energy can be more usefully understood and described as potential for energy. When a body has potential energy, it has the capacity to do work. When a spring is compressed, work has been done on it. If it is released, the spring can do work. The potential (for) energy that it has allows the spring to do work.
locating
+
* [[Image:Energy%20for%20KOER_html_7e8255f0.gif]]It is also useful to think of potential energy in terms of change in energy level with respect to a zero. The surface of the earth has been arbitrarily assumed to be at zero potential energy.
coal reserves on a map
+
* The potential for energy is with respect to a zero defined for a system. The potential energy is, therefore, always to be referred to in terms of a system. The potential energy of the object-earth system was changed when it was lifted to a height ‘h’.
 
 
 
   
 
   
|-
+
If an object of mass ‘m’ is raised to a height
|
+
‘h’, work has been done.
 
 
  
 
   
 
   
|
+
Work done = m x g xh
Biomass
 
energy
 
  
 
   
 
   
|
+
= mgh
Energy
 
can be converted from one form to another – can be produced
 
from household waste.
 
  
 
   
 
   
|
+
This is stored in the object as potential energy
Biomass
+
and when the object falls, gets converted into kinetic energy. In
energy is the energy produced by the waste material and dead
+
this particular case, the potential energy is referred to as
parts of living objects.
+
gravitational potential energy. An object can also possess potential
 +
energy if it is put under strain. Then it has energy stored in it
 +
because of the work done to bring it in that condition. In a time
 +
piece, the main spring, for example, once wound keeps unwinding and
 +
driving the clockwork mechanism for many hours. Here the coiled
 +
spring has energy stored in it because of the work done on it while
 +
winding.
  
 
   
 
   
|
+
Potential energy is the potential for energy that is built in an
Separates
+
object. The energy that an object possesses when it is lifted to a
the solid wastes , like vegetable wastes,dead leaves from wastes
+
height or it is put under strain is potential energy.
like plastics,glass, etc., before disposing.
 
  
 
   
 
   
|
+
==== Activity 1 (Self-evaluation for student) ====
Visit
 
to a biogas plant
 
 
 
 
   
 
   
|-
+
[[Image:Energy%20for%20KOER_html_m13b54311.gif]]Knowing
|
+
that the PE at the top of the stairs is 50 J, what is the potential
 
+
energy at the various positions?
  
 
   
 
   
|
+
<br>
Solar
 
energy
 
  
 +
   
 +
=== Potential Energy – Kinetic energy changes during free fall ===
 
   
 
   
|
+
<br>
Sunlight
 
is a mixture of light of various wavelengths, each of different
 
energy. Among the radiations emitted by the sun the Ultraviolet
 
and infrared radiations has more energy. This energy can be
 
harnessed in different ways so that we can use this energy as an
 
alternative source for fossil fuels. This is free pollution and
 
renewable form of energy.
 
  
 +
 
 +
=== Conservation of energy ===
 
   
 
   
|
+
The key idea here is that the total energy of the
Learns
+
system is conserved. Potential energy can be converted into kinetic
that Sun's energy can also be trapped and used as a form of
+
energy and vice versa. But the total energy remains unchanged.
energy in their daily life.
 
  
 
   
 
   
|
+
In more general terms, the law of conservation of
Uses
+
energy states that energy can neither be created nor destroyed; but
Solar equipments like solar heater, solar lights,Solar cookers
+
can be transformed from one form to another.
etc., in their daily life as they use solar energy-renewable and
 
pollution free energy.
 
  
 
   
 
   
|
+
==== Activity : Conservation of mechanical energy in a pendulum ====
Exhibiting
+
the solar equipments
+
==== Objectives: ====
 +
 +
# To study the motion of a simple pendulum
 +
# To observe the different factors on which the motion of a simple pendulum depends
 +
# Develop an understanding that gravity is a conservative force
 +
 +
==== Method: ====
 +
 +
[[Image:Energy%20for%20KOER_html_m72c98b84.png]]Use
 +
the PhET simulation Pendulum Lab.
  
 
   
 
   
|-
+
For this we will need to open an application
|
+
called PhET on the computer. You can find PhET under Applications&gt;
 +
Education&gt; Science. PhET is an educational resource that contains
 +
computer demonstrations of experiments and activities. When we click
 +
on Play with sims – it will open simulations in various subjects.
 +
We will click on Physics and scroll down to the simulation on
 +
Pendulum Lab.
  
 +
 +
When we want to open a simulation, we click on
 +
the green rectangle which says “Run Now”.
  
 
   
 
   
|
+
==== Running the simulation ====
Wind,
+
Running water, Ocean-Waves and tides and Ocean thermal gradients,
+
'''Screenshot #1'''
Geothermal energy as a source of energy
 
  
 
   
 
   
|
+
[[Image:Energy%20for%20KOER_html_m6465bb7e.png]]'''Questions:'''
Learns
 
that other than sun there are many other sources of energy which
 
are easily available, pollution free and inexhaustible.
 
  
 
   
 
   
 +
# Notice where the pendulum is – is it higher, lower or at the same level as the central position?
 +
# Notice the graph – what are the two variables on the bar chart?
 +
# What do you think will happen to the pendulum next?
 +
 +
Screenshot #2
  
 +
 +
[[Image:Energy%20for%20KOER_html_m4498abd8.png]]'''Questions:'''
  
 
   
 
   
|
+
# Notice where the pendulum is – has it moved? What can you say about its movement?
Wind
+
# Notice the graph – what are the variables on the bar chart?
energy is the energy of motion of air is the energy which is
+
# What are the values of PE and KE as compared to total energy?
inexhaustible and permanent source of energy where there will
+
always be winds. (See note below table)
+
Screenshot #3
  
 
   
 
   
|
+
[[Image:Energy%20for%20KOER_html_706b8b67.png]] '''Questions:'''
Uses
 
the alternative energy source which is easily available to them.
 
  
 
   
 
   
|
+
# Notice where the pendulum is – has it moved? Is it higher or lower than the central position?
Making
+
# Did you notice anything about the speed of the bob as it moves from one extreme position to another?
a Phirki, a common toy of a child which works by a wind force.
+
# Notice the graph – what are the variables on the bar chart?
Visit to a Hydroelectric power station.
+
# What has happened to the values of the KE and PE as compared to total energy?
 
+
# What do you think is happening? Is this what you will think will happen when you try this experiment? Why? Why not? What is different?
 
   
 
   
|-
+
'''Screenshot #4'''
|
 
 
 
  
 
   
 
   
|
+
[[Image:Energy%20for%20KOER_html_1fe1122b.png]]<br>
Small
 
scale storage, large scale storage
 
  
 
   
 
   
|
+
'''Questions:'''
Various
 
sources of generation of power is associated with a problem of
 
power fluctuates During day time power can be supplied fully from
 
different sources whereas to work during night time storing up of
 
energy is necessary. Depending upon the purpose energy can be
 
stored in small scale and also large scale. For small scale
 
storage primary cells and secondary cells can be used. But to
 
meet the large energy requirements of homes and industry storage
 
batteries are impractical.
 
  
 
   
 
   
|
+
# Notice where the pendulum is. This extreme position to the right is at a different height than before. Why? What role does friction play and where does it come from
Learns
+
# Look at the graph – what are the variables in the bar chart? Where has the thermal energy come from?
that harnessed energy can also be stored to use when in need.
+
# What do you expect will happen to the simple pendulum?
 +
 +
==== Mechanics of the simple pendulum ====
 +
 +
The motion of a pendulum is a classic example of
 +
mechanical energy conservation. A pendulum moves it sweeps out a
 +
circular arc, moving back and forth in a periodic fashion. Neglecting
 +
air resistance (which would indeed be small for an aerodynamically
 +
shaped bob), there are only two forces acting upon the pendulum bob.
 +
One force is gravity. The force of gravity acts in a downward
 +
direction and does work upon the pendulum bob. However, gravity is an
 +
internal force (or conservative force) and thus does not serve to
 +
change the total amount of mechanical energy of the bob. The other
 +
force acting upon the bob is the force of tension. Tension is an
 +
external force and if it did do work upon the pendulum bob it would
 +
indeed serve to change the total mechanical energy of the bob.
 +
However, the force of tension does not do work since it always acts
 +
in a direction perpendicular to the motion of the bob. At all points
 +
in the trajectory of the pendulum bob, the angle between the force of
 +
tension and its direction of motion is 90 degrees. Thus, the force of
 +
tension does not do work upon the bob.
  
 
   
 
   
|
+
Since there are no external forces doing work, the
Uses
+
total mechanical energy of the pendulum bob is conserved.
the storage batteries such as dry cells and uninterrupted power
 
supplies for continuous operation of their costly equipment,
 
computers and other strategic gadgets.
 
  
 
   
 
   
|
+
=== Power, energy units and conversions ===
Exhibiting
+
the dry cells and secondary cells used in the UPS
+
One important aspect of the processes producing or
 +
using or/and converting energy from one form to another is the rate
 +
at which this is done. For example, two persons perform equal
 +
amounts of work by lifting identical boxes from the ground level and
 +
keeping them on a shelf .One of them does this rapidly while the
 +
other does it slowly. Although the total work done by each person is
 +
the same, the two persons work at different power levels. The faster
 +
working person converts his body’s chemical energy into work at a
 +
more rapid rate than the slowly working person
  
 
   
 
   
|-
+
Power is the rate at which work is done or energy
|
+
is used or supplied and may therefore be calculated by dividing the
 
+
work done (or energy used or supplied) in the process by the time
 +
taken by the process. Work
 +
is done over a certain time. Rate of doing work is power. Power is
 +
different even if energy is the same.
  
 
   
 
   
|
+
Energy or work is measured in Joules (J) and time
Atoms,
+
is measured is seconds (s) and so the unit of power is the '''joule
Isotopes
+
per second (J/s),''' This unit is given the special name '''WATT (W)'''
 +
where
  
 
   
 
   
|
+
1watt =1 J/s
The
 
smallest entities into which the elements can be divided are
 
called atoms. The protons and neutrons which are the particles
 
of atoms bound together immensely by strong forces called nuclear
 
force. Atoms of the same element which exist in different forms
 
as a result of having different numbers of neutrons in their
 
nuclei are called isotopes.
 
  
 
   
 
   
|
+
1000watt =1
Understands
+
kilowatt=1kw
the basic structure of the atom, atomic weight, and isotopes.
 
  
 
   
 
   
|
+
1000,000 watt =1megawatt=1MW
  
 +
 +
1,000,000,000watt =1gigawatt=1GW
  
 
   
 
   
|
+
1,000,000,000,000watt =1terawatt=TW
Exhibiting
 
the periodic table of elements, exhibiting the chart of different
 
isotopes
 
  
 
   
 
   
|-
+
A commercial unit energy that we often hear about
|
+
on out electricity bills is the '''kilowatt hours (kwh).'''
 +
1kilowatt hour is the energy used or supplied when 1kw power is used
 +
or supplied for one hour. '''1kwh is equal to 3.6 million joules.'''
  
 +
 +
=== Energy Units and conversions ===
 +
 +
The basic unit for the measurement of energy in
 +
the metric system is the joule, but there are also other units in
 +
common usage. The kilowatt hour is usually used to describe
 +
electrical energy. The '''calorie''' which is defined as the amount
 +
of heat energy required to raise the temperature of 1g of water
 +
through 1degree Celsius, is the unit primarily used to measure heat
 +
and also to describe the energy content of food stuff.
  
 
   
 
   
|
+
= Energy in the world =
Nuclear
 
fission
 
 
 
 
   
 
   
|
+
The transformations of energy from one form to
Nuclear
+
another and the efficiency of the transformation processes are
fission is a process of releasing a large amount of energy by
+
studied in Physics, Chemistry and Biology. While so far we have
hitting a neutron on unstable elements and making them split.  
+
discussed potential energy and kinetic energy (expressed as thermal
This is carried out in a nuclear reactor.
+
energy in molecules), we see around us energy in various forms such
 +
as electrical energy, solar energy tidal energy hydro energy,
 +
geothermal energy and so on. All these forms of energy fall under the
 +
two categories of energy kinetic and potential. Potential energy is
 +
the stored energy and the energy of position and can be understood as
 +
potential for energy. Chemical energy, nuclear energy, stored
 +
mechanical energy and gravitational energy are all forms of potential
 +
energy.
  
 
   
 
   
|
+
In this section, we will explore the following:
Understands
 
the process of generating nuclear energy by the process of
 
nuclear fission.
 
  
 
   
 
   
|
+
# Matter contains internal energy caused due to molecular motion
Pupil
+
# Energy can be conveted from one form into another
draw the diagrams of the nuclear reactors
+
 
+
=== Energy in matter ===
 
   
 
   
|
+
The molecules in every bit of matter solid, liquid
 
+
or gas are in a continual state of motion. This random motion of
 +
molecules(or atoms) constitute an internal kinetic energy or thermal
 +
energy that an object possesses even though the object as a whole
 +
may not be in motion. Thermal energy is thus manifestation of the
 +
motion of the molecules of a substance. A change in the thermal
 +
energy of an object can be brought about by supplying heat to the
 +
object. For example, by repeatedly hitting a block of metal with a
 +
hammer, its atoms are caused to move rapidly, thereby raising the
 +
thermal energy of the metal block which as a result becomes hot.
  
 
   
 
   
|-
+
The primary source of all energy on the Earth is
|
+
the Sun, though there are some small amounts of energy that come from
 
+
the Earth's interior as well as cosmic radiation. Tidal energy is
 +
also caused by the gravitational pull of the Earth. Powered by the
 +
Sun, energy constantly flows through the Earth's surface and
 +
environment.
  
 
   
 
   
|
+
=== Laws governing the energy of the universe ===
Nuclear
 
fusion
 
 
 
 
   
 
   
|
+
Studying the flow of energy and understanding the
Joining
+
processes in the world is called thermodynamics. This branch of
together of lighter atoms to form heavier atoms and releasing
+
science involved asking questions about how processes happen in the
enormous amount of energy is nuclear fusion. Nuclear fusion
+
world around us. For example, why are certain processes irrevesible?
reaction is happening in the sun.
+
What makes a chemical reaction takes place? When does heat flow
 +
from one object to another?
  
 
   
 
   
|
+
Exploration of these concepts resulted in the
Understands
+
formulation of two laws:
that we are getting tremendous amount of energy by the process of
 
fusion reaction in the sun.
 
  
 
   
 
   
|
+
# The first law of thermodynamics states that the total energy of a system and its surroundings remains constant. In other words, the energy of the universe is constant. This law implies that energy is conserved and the energy content of the system takes two forms - work and heat.
Differentiate
+
# The second law of thermodynamics states that the entropy of the universe is always increasing. This can be summarized by stating that the universe always moves in a direction of increasing randomness.
between nuclear fission and nuclear fusion
 
 
 
 
   
 
   
|
+
=== Some processes of energy conversion ===
 
 
 
 
 
   
 
   
|-
+
We have seen that energy occurs in various forms.
|
+
These different forms of energy can be converted from one form to
 +
another.
 +
 
 +
 +
* For example, when we switch on an electric light firstly, we can see the transfer of electrical energy from the power plant to our home, and then the conversion of electric energy into heat energy, part of it into visible light. This light energy is not destroyed but it is absorbed by the walls, ceiling and floor and other objects, finally to be converted into heat.  Electric energy → heat energy+ light energy
 +
* In a power plant, chemical energy stored in fossil fuels such as coal, oil or gas is converted into heat energy in the boiler by combustion. This heat energy changes water from liquid state to steam. This heat energy of steam is converted in part, into mechanical energy in the steam turbine. This mechanical energy is then converted into electrical energy in the generator. From the generator it is transferred by the electric cables to various points where it can be used for further transfer to homes and industries etc.,  Chemical energy → heat energy → steam energy → mechanical energy electrical energy → light energy+ heat energy+ mechanical energy
 +
* In the running of a car the chemical energy hidden in the explosive mixture of petrol vapour and air is converts by the spark into heat energy. The heat energy, in turn is converted in part, into mechanical energy of motion of the pistons in the cylinders. The mechanical energy of the pistons is transferred to the drive shaft and from there to the wheels to move the car.  Chemical energy → heat energy → mechanical energy
 +
* All biological processes throughout the domain of living things can also be shown to be energy conversion processes. The digestion of food is a combination of rather complicated processes but what it amounts to is the transformation of chemical energy locked in the food into heat energy to keep the body warm, and into mechanical energy to enable the body to do work by moving its various parts or itself as a whole besides synthesizing some compounds. There is also some conversion into electrical energy to establish communication between various parts of the body through the nervous system.
 +
* Chemical energy → heat energy + mechanical energy + electrical energy  In all the above examples energy is converted from one to another, but the total energy in any energy conservation process always remains constant; that is energy can neither be created nor destroyed. This is the law of conservation of energy.
 +
 +
= Biological energy flow =
 +
 +
We saw earlier that energy flows constantly
 +
through the Earth and its environment. Plants fix the solar
 +
radiation into carbohydrates and form the basis of much of the energy
 +
flow in the world. Either through the food chain or through the
 +
accumulation as fossil fuels, this accounts for the bulk of the
 +
energy in the world.
  
 +
 +
== Concept Flow ==
 +
 +
# Energy flows are essential to life processes and we need to study biological energy flows also to understand flow of energy.
 +
# We cannot discuss energy without discussing the connection with food and how energy flows through living organisms through food. This flow of energy through living organisms is called a food chain.
 +
 +
=== Energy flow in an ecosystem ===
 +
 +
An ecosystem is a community where living and
 +
non-living things interact. There are two main processes in an
 +
ecosystem – energy flow and nutrient flow. The energy flow in an
 +
ecosystem happens through the food chain.
  
 
   
 
   
|
+
=== Activity: Energy flow through a food chain ===
Threats
+
from fossil fuels, combustion of fuels, effects of carbon
+
==== Objectives ====
monoxide and carbon dioxide, Thermal pollution and effects of
+
nuclear radiations
+
# To understand the way energy flows in an ecosystem
 +
# To explore the connections between different cycles and processes in an ecosystem
 +
 +
==== Method ====
 +
 +
Watch the following videos on food chain
  
 
   
 
   
|
+
* Food chain in Africa [[http://www.youtube.com/watch?v=3Bn7wdCP2v4&feature=related]]
There
+
* Interactions in an ecosystem [[http://www.youtube.com/watch?v=XJ6VtduDSyY&feature=related]]
are a numerous environmental problems associated with the
+
* Description of a food chain and web [[http://www.youtube.com/watch?v=9eZBzfnAogU&feature=related]]
extraction, transportation and utilisation of fossil fuels.  
+
* Interactions and energy flow in an ecosystem [[http://www.youtube.com/watch?v=o_RBHfjZsUQ]]
Understands that there are harmful effects on the environment by
+
the over use of fossil fuels, electricity generating plants, and
+
<u>'''Questions:'''</u>
also nuclear reactors.
 
  
 
   
 
   
|
+
* When we say food web, what comes to your mind? Why do you think it is called food web?
 +
* What are the implications of laws of thermodynamics on how much energy is transferred in a food chain?
 +
* Can you think why there are few consumers and large number of producers? What happens when a consumer eats a producer?
 +
* In the local ecosystem, provide examples of each of these categories in your area – producer, consumer and decomposer?
 +
* For this web to work properly, what is needed?
 +
* What is energy flow? How does it flow – from small organisms to large or large organisms to small? Why do you think so? What elements do you observe in the ecosystem that give you this idea?
 +
* Is the tiger 'bad' because it ate the goats? Why is the tiger eating the goat?
 +
 +
==== Methods of energy flow ====
 +
 
The
 
The
burning of fossil fuels releases a variety of noxious gases and
+
laws of thermodynamics we saw earlier govern the processes in a food
particulate matter into the atmosphere. Carbon monoxide and
+
chain also. For example, the first law tells us that an organism can
carbon dioxide which are the pollutants produced by the burning
+
only use the energy it receieves whereas the second law tells us that
of fossil fuels constitute a serious environmental problem. All
+
not all of the energy received by an organism can be used – some of
electricity generating plants produce unwanted heat which is
+
it will be lost as heat. At each level of the food chain, the amount
released to the atmosphere. Nuclear reactors harmful substances
+
of energy that gets transferred to the next trophic level is only a
which can are very harmful to living organisms.
+
portion of the energy present in the lower level. This fraction
 +
varies widely across ecosystems. When finally organisms die and
 +
decay they pass the materials of life in simple forms to other
 +
organisms (nutrient flow). This energy flow is not cyclic –
 +
continuously less and less energy is available. So then, how do
 +
ecosystems continue? They depend on an external source of energy
 +
called the Sun. If the Sun's energy is not available in usable form,
 +
life on Earth may not be possible any longer.
  
 
   
 
   
|
+
= Conventional sources of energy =
 
 
 
 
 
   
 
   
|
+
We saw how the solar energy is responsible for
 
+
producing organic compounds that sustain energy flow in the living
 +
world. Availability of energy resources and harnessing them for
 +
multiple applications have concerned the human society for centuties.
 +
Advances in technology and society have always been linked to the
 +
access of and use of natural energy resources. In this section, we
 +
will look at some of the major sources of energy that are used by
 +
human beings in our endeavours.
  
 
   
 
   
|-
+
== Concept flow ==
|
+
 
+
Some key ideas we will explore in this section
 +
are:
  
 
   
 
   
|
+
# Solar enerrgy is the source of almost all energy on the Earth
Need
+
# Fossil fuels are exhaustible and needs thousands of years to form.
for Judicious Use of energy, minimising energy
+
# Biomass energy which comprises parts of living things is also a source of energy.
 
 
 
   
 
   
|
+
=== Forest ===
Depletion
 
of energy sources is too fast. Therefore mankind has to adopt a
 
judicious approach towards consumption of energy sources. Mankind
 
has to adopt different steps to minimize the wastage of energy.
 
 
 
 
   
 
   
|
+
Firewood has been the major source of energy
Understands
+
during most of man’s history and it continued to remain the most
that there is a need to use the available energy judiciously
+
important fuel until the middle of nineteenth century. Firewood is
 +
obtained from the forests and is primarily used for heating and
 +
cooking. The other fuel which has been traditionally used here is
 +
animal dung cakes. The animal dung mainly consists of undigested
 +
plant material which on drying, gives a product that readily burns.
 +
One of the disadvantages of both firewood and animal dung cakes as
 +
fuels is that they give a lot of smoke on burning.
  
 
   
 
   
|
+
With the industrial revolution in Europe, people
Adopts
+
learned to transform the energy from coal to mechanical energy in
steps to minimize wastage
+
machines. This led to increased demand for energy. The discovery of
 +
coal, followed by oil and natural gas fulfilled these demands to a
 +
large extent and these fuels since then have been the primary sources
 +
of world’s energy.
  
 
   
 
   
|
+
=== Fossil fuels ===
 
 
 
 
 
   
 
   
|}
+
All these fuels - coals, oil and natural gas- are
Running water is an easily
+
derived from the slow decay of living organisms such as trees, algae
available source of energy. It is available free and does not pollute
+
and small marine animals for millions of years and are therefore
the environment. Ocean energy-Tides, rising and falling of the ocean
+
known as fossil fuels. The fossil fuels are being consumed at an
level due to the moon's gravitational pull can be harnessed to
+
appreciable rate. Although their new deposits continue to be
extract energy. Waves,which keep the ocean water in continual motion
+
discovered, the world reserves of these fuels are limited. Further,
can be used to produce energy. The heat contained in the ocean waters
+
these energy sources take millions of years to form and therefore
heated by the sun can be converted into electricity by utilising the
+
fossil fuels are also known as non-renewable sources of energy.  
difference in temperature between the surface and lower depths.
+
These fuels once exhausted cannot be replaced quickly when exhausted.
Geothermal energy -Underground water which oftens gets heated and
+
Hence these are also called as exhaustible resources.
produces steam and hot water and comes out as hot springs and geysers
 
can be utilised.
 
  
 
   
 
   
= Syllabus =
+
=== Formation of fossil fuels ===
 
   
 
   
# Kinetic and Potential Energy – the definitions and formula
+
==== Coal ====
# Heat and Sound
 
# Forms of energy – main sources of energy, changes from one form to another
 
# Law of conservation of energy
 
# Force causes change in a body; measurement of work
 
# Structure of atom
 
 
   
 
   
= Curricular Objectives =
+
[[Image:Energy%20for%20KOER_html_m7a3827ce.jpg]]Fossil
 +
fuels-coal, oil and natural gas-are the result of decomposition of
 +
living matter. Coal is obtained from dead plant matter which consists
 +
primarily of carbon, hydrogen and oxygen.
 +
 
 
   
 
   
# The first objective is to introduce children to basic concepts of work. We introduce that work always involves overcoming some opposing force. We then look at work done is directly proportional to both the applied force and the distance through which the force acts.
+
[[Image:Energy%20for%20KOER_html_m6d44a4fd.jpg]]On
# In this section, the children are introduced the meaning of energy. We introduce that the body moves and does work only when the energy is supplied to it. This is followed by the concepts of kinetic and potential energy.
+
dry land, this matter rots away by bacterial action in presence of
# In this section, we introduce the different forms of Kinetic and potential energy and conversion of one form to another to meet our needs for home and industry.
+
atmospheric oxygen to form carbon dioxide and water. But in swampy
# In this section we introduce the meaning of power, units of power and the energy requirements for various activities
+
locations, the dead plant matter is covered with water and is,
# .In this section,we introduce the conventional sources of energy -fossil fuels-formation of fossil fuels, supply of fossil fuels, processing of fossil fuels- coal and petroleum and also the Biomass energy-raw materials used in this and brief introduction of the biogas plant.
+
therefore, protected from the oxidising action of air. Instead, it
# In this section we introduce the non conventional sources of energy-solar energy which is readily available to us ,inexhaustible, free from pollution. We have also disussed harnessing solar energy in different ways for different purposes. We have also discussed other non conventional sources of energy like wind energy, ocean energy-energy from tides, and energy from waves-Geothermal energy and also the methods of storing energy.
+
is attacked by bacteria which do not require free oxygen in order to
# In this section , children are introduced the basic structure of the atom-no of protons, no of electrons and the no of neutrons in each atom . Once the children are introduced the structure of atom and then we introduce the concept of isotopes and then the uranium isotopes which involves in fission process. We further introduce the nuclear reactors-thermal and fast breed reactors. After this we discuss briefly what is happening inside the sun, how energy is generated in the sun , fusion processes and fusion reactors.
+
live. In the process oxygen and hydrogen of the dead plant matter
# In this section, we briefly discuss the numerous environment problems associated with the extraction, transportation and utilization of fossil fuels, the effects of burning fossil fuels-effects of carbon Dioxode and
+
gradually escape and the residue, therefore, becomes richer and
# Carbon Monoxide on the environment,‘thermal pollution' which basically refers to the detrimental effects of discharges of unwanted heat into the environment.
+
richer in carbon. The end product of the bacterial action is a
# In this section, we create awareness about the need for judicious Use of energy and how to minimise wastage so that we can then be put to some useful 'use' in future and also to remember, energy saved is energy produced.
+
soggy, carbon-rich substance called peat.
 
= Energy =
 
 
'''E'''nergy is the basis of human life. Every
 
single aspect of human experience whether it be in the external world
 
or what we do or what is done to us can be adequately described
 
either as a transfer of energy in one form from one place to another
 
or the transformation of energy from one form to another.
 
  
 
   
 
   
What is the meaning of energy? How does one
+
[[Image:Energy%20for%20KOER_html_m29549bc5.jpg]]Over
measure it? What are the various forms in which energy manifests
+
long periods of time the peat is covered with sand, silt and clay.
itself? How is energy obtained and transformed from one form to the
+
As peat gets compressed and heated further due to geological changes,
other? How can energy be conserved? How do the production and
+
more gases are forced out and therefore the proportion of carbon
utilization of energy in its various forms affect our environment?
+
continues to increase. In this way, peat is gradually converted into
 +
various forms of coal such as lignite, bituminous coal and
 +
anthracite.
  
 
   
 
   
== Work, measurement of work ==
+
==== Petroleum and natural gas ====
 
   
 
   
We often use the terms work in ordinary
+
In contrast to coal, the raw material in the
conversation. We say for example “This job requires a lot of work”.
+
formation of oil and natural gas consists mainly of marine organisms,
What does ‘work’ really mean here? If we lift a box from the
+
mostly plants that grow near the surface of the sea. When these
ground level and place it on a high shelf, we feel tired after the
+
organisms die and accumulate in basins, where the water is stagnant,
job is completed; we feel that we have done some work. How is this
+
they are also protected from atmospheric oxidation. The dead marine
done? Gravity pulls the box and hence we are doing work against this
+
matter is decomposed by anaerobic bacteria. Oxygen, nitrogen and
gravitational force. This is true for any type of work.
+
other elements escape leaving mainly compounds of carbon and hydrogen
 +
called hydrocarbons. The accumulating covering layer of sediments
 +
provides heat and pressure that convert the hydrocarbon material into
 +
droplets of liquid oil and bubbles of natural gas. As more
 +
sedimentary deposits are laid down over periods of time, the pressure
 +
increases and the oil and gas are forced into nearby porous sand or
 +
sandstone. Gradually the oil and gas migrate upward through the sand
 +
and they then either escape to the surface or are trapped beneath
 +
layers of clay stone. This migration process separates the oil from
 +
underground water because water molecule readily adhere to sand
 +
whereas oil molecules do not. Thus the oil tends to collect in the
 +
pore spaces of sandy rocks beneath roof rocks with natural gases on
 +
the top.
  
 
   
 
   
Work always involves overcoming some opposing
+
=== Biomass Energy ===
forces. Suppose that instead of lifting the box, we push it across a
 
rough floor. Suppose that instead of lifting the box, we push it
 
across a rough floor. In this case, we are not working against the
 
gravitational force-the box is at the same height throughout the
 
movement. Instead, we are now working against the frictional force
 
that exists between the moving the box and the floor.
 
 
 
 
   
 
   
=== How do we measure work here? ===
+
Fossil fuels are derived from plants, trees and
 +
animals that lives millions of years ago. It took the remains of
 +
these organisms millions of years of burial under tremendous pressure
 +
and the internal heat to turn into coal, oil, or gas that we use as
 +
fuel today. We cannot get fossil fuels from the plant and animal
 +
waste that we produce today. But they, too form a substantial source
 +
of energy in the form of biomass. Biomass means the waste material
 +
and dead parts of animals that are living today. It includes
 +
garbage, industrial waste, crop residue, sewage and plant waste such
 +
as dead leaves and wood. These wastes can be both wet and dry. Wet
 +
wastes are in the form of animal excreta or domestic and industrial
 +
residues. Dry wastes refers to leaves, wood, paper, straw, fruit
 +
skin and others. There are two ways of using biomass as a source of
 +
energy. One is to burn the dry biomass directly to produce heat and
 +
generate steam. Another method is to convert this biomass into
 +
gaseous fuels called biogas by fermentation.
 +
 
 
   
 
   
We know that there is some cause (we have defined
+
The raw material used for the production of biogas
it as force) that results in a change in state of an object. When
+
is cow dung mixed with water which is taken in an insulated,
such a change in state occurs, it often results in a change in energy
+
air-tight container called digester. In the digester, bacteria break
of the object.
+
the raw material into simpler chemicals by a process known as
 +
anaerobic decomposition. Other bacteria then convert the chemicals
 +
into a biogas for fuel. The gas consists of mainly methane and is
 +
drawn out through a gas outlet pipe.
  
 
   
 
   
We had also looked at what happens when a force
+
Wet wastes from household and industries too can
acts over a period of time and we saw that the Impulse I = F x t =
+
be used to produce methane gas. Wastes may be dumped in deep pits.
m(v – mu) is the change in momentum of the body.
+
Wells are then drilled down into the waste. A pipeline is then
 +
drilled down into the waste. A pipeline is then to recover the gas
 +
produced by the natural decomposition of the material.
  
 
   
 
   
Let us now look at what happens when Force acts on
+
=== From fossil fuel to electricity ===
an object over a distance along the direction of the force. In we say
 
work is done by a force if the force acts on an object over a
 
distance and we say that the work done W = Force F x distance
 
travelled along the direction of the force.
 
 
 
 
   
 
   
Thus W = F x d if the distance travelled d is in
+
The most convenient usable form of energy is
the same direction as the force. If the direction in which the object
+
electricity. In all the sources of energy above, the heat generated
is moving is at angle θ then the distance travelled in the direction
+
from the combustion of fuel is used to boil water to produce steam
of the force would be d Cos θ and the work done would be W[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_6d9bf88e.gif]]
+
which powers a turbine. This mechanical energy of turbine is
= f x d Cosθ
+
converted into electricity in generators. These stages involve
 +
various losses and therefore the overall efficiency of these plants
 +
is never more than 40 percent. It is, however, possible to cut short
 +
the above energy conversion stages and convert heat from the
 +
combustion of fuels directly into electricity using a magneto-hydro
 +
dynamic generator, popularly known as MHD generator, which works on
 +
the basic phenomenon of electromagnetic induction. Another method of
 +
increasing the efficiency of power generation is also through the use
 +
of combined cycle power plants.
  
 
   
 
   
If the force is acting perpendicular to the
+
=== Processing of coal and petroleum ===
direction of the work done, there is no work done. If you are
 
carrying a heavy bag in your hand and walking, though you may feel
 
tired, no work is done in the physical sense, because there is no
 
energy change that has occurred for the bag.
 
 
 
 
   
 
   
Work done, is defined as a particular form of
+
Coal, which is essentially pure carbon, is chiefly
product of two vectors – force and displacement. Such a product is
+
used as a combustion fuel. The reaction of carbon with atmospheric
called the scalar product and the resulting quantity is a scalar. In
+
oxygen to produce carbon dioxide is an exothermic reaction that
the context of work done, this is easy to understand. You don’t do
+
releases about 7,840 kilocalories/kg of carbon and this reaction is
work in a particular direction – you just do work.
+
responsible for the heat energy derived from burning coal. Burning
 +
of coal produces large quantities of fly ash and noxious gases such
 +
as a sulphur dioxide and related compounds which cause atmospheric
 +
pollution. Coal is therefore converted into a cleaner fuel, coke, by
 +
heating crushed coal to high temperatures in the absence of air.  
 +
Coal can also be converted into liquid and gaseous fuels which can
 +
partially replace the fuels derived from petroleum.
  
 
   
 
   
The unit of work done is joules. 1 J of work is
+
Unlike coal and natural gas which can be used
said to be done when a force of 1 N causes a displacement of 1 m.
+
directly as fuels without processing, petroleum or crude oil is not
 
+
directly usable. The name ‘petroleum’ is derived from the Latin
+
words ''petra'' meaning ‘rock’ and ''oleum''
When work is done, it is done over a certain time.
+
meaning ‘oil’. Therefore, it means rock oil, to distinguish it
The rate of doing work is defined as the power. Power is defined as
+
from animal or vegetable oils. Petroleum, also often called crude
(work done)/ time taken.
+
oil, is a mixture of hundreds of hydrocarbon compounds together with
 
+
small amounts of compounds of other elements. The exact composition
+
of crude depends upon many factors such as its age and the types of
Power = work done/ time
+
organisms from which it is formed. So, every deposit of crude oil
 +
is a unique mixture whose exact composition differs even from
 +
deposits separated from it vertically or horizontally by a few metres
 +
of rock. Natural gas is normally associated with crude oil. It is a
 +
mixture of gaseous hydrocarbons, mainly methane and ethane. The
 +
non-hydrocarbon compounds present in crude oil are mainly compounds
 +
of sulphur, nitrogen and oxygen. Other elements present in very
 +
small amounts include vanadium, nickel, chlorine, arsenic and lead.
  
 
   
 
   
= force x displacement/ time
+
==== Detection of Oil ====
 
 
 
   
 
   
= force x velocity
+
The method generally used for locating oil
 +
deposits is the seismic survey. Shock waves generated by surface
 +
explosive charges travel through rock layers and are reflected back
 +
by various geological structures and possible locations where oil
 +
might be trapped can be found. To find whether oil is really present
 +
and whether it can be economically extracted, it is necessary to
 +
drill a well.
  
 
   
 
   
Its unit is Watt.
+
==== Extraction and refining of Oil ====
 
 
 
   
 
   
Does work always involve change? It may seem from
+
Once the oil has been found by drilling the well,
the previous discussion that any change involves work. Sometimes the
+
the next step is to operate the well; that is, to raise the oil to
change may not be easily visible. For example, is the boy in the fig
+
the surface. After extraction, the oil is usually transported to a
doing some work? One may say he is not as nothing seems to be
+
refinery through pipelines. From offshore platforms, the oil is
changing. The position of the boy remains the same, the position of
+
sometimes transported to the shore in large tankers. The natural gas
the weight remains the same and no object in the picture is moving.
+
produced in the process is also transported by large pipelines.
But if one were to hold the weight in one’s outstretched hand
 
standing in the same position, one would quickly feel tired as one
 
loses energy.
 
  
 
   
 
   
== Key vocabulary ==
+
Crude oil is processed in a refinery by fractional
+
distillation. This process involves heating the crude oil in a tall
# Friction -A force opposing the relative motion of two surfaces in contact.
+
tower so that various components are distilled out of it and can be
# Gravity- the force with which earth attracts every object towards its centre.
+
trapped at various levels in the tower. In this process the use is
 +
made of the fact that the different hydrocarbon compounds in the
 +
crude have different boiling points and hence can be separated at its
 +
boiling point. The lightest compounds such as gases which have low
 +
boiling points rise to the top and the heavier oils with higher
 +
boiling points are collected lower down.
 +
 
 
   
 
   
== Additional web resources ==
+
The various fractions may then be further
+
processed by cracking or refining, both of which involve the use of
'''1)''' [[http://www.youtube.com/watch?v=8J_z3_3pue0]]
+
catalysts-substances which facilitate the chemical reactions without
 +
themselves undergoing any change. Catalytic cracking, often called
 +
cat-cracking, is a means of breaking down the heavier distillates to
 +
form lighter compounds.
  
 
   
 
   
'''2)
+
The various fractions obtained after refining are
[[http://www.youtube.com/watch?v=sOa7EpJf89I&feature=related]]'''
+
used for different purposes The gas fraction, like natural gas, is
 +
used chiefly as a fuel for heating. Petrol is used in spark ignition
 +
internal combustion engines that require a fairly volatile fuel.
 +
Kerosene is used as a lighting and cooking fuel in villages, and also
 +
in tractors and jet engines. Diesel is used in diesel engines.
  
 
   
 
   
= Energy, types of energy-Kinetic and potential =
+
= Non conventional Sources of energy =
 
   
 
   
When an object is moved against a force, work is
+
The conventional sources of energy discussed in
done and energy is spent in the process. Thus we say “A person
+
the previous section are exhaustible and cannot be quickly replaced
must have a lot of energy to do a hard day’s work”. In fact one
+
when exhausted. It takes millions of years for these sources to be
way to define energy is: Energy is the capacity to do work.
+
formed from the decay of living organisms. These sources are,
 +
therefore, also known as non-renewable sources of energy. In
 +
contrast, we have another class of the sources such as the sun, wind,
 +
waves, tides, and geothermal heat which are inexhaustible. These
 +
sources of energy are, therefore, known as renewable sources of
 +
energy.
  
 
   
 
   
The word ‘energy’ is derived from the Greek
+
== Concept flow ==
'''''energia''''''''-en means ''''''''‘in’''''''''
+
and''' '''''ergon'''''''', means
+
# Unlike fossil fuels and to some extent, forest and biomass, non-conventional sources of energy are renewable and can potentially be used for longer periods of time
''''''''work'''''.
+
# A major problem in harnessing these sources of energy is that the energy released by them is highly diffused as compared with the energy obtained from fossil fuels or nuclear fuels.
 +
# Considerable research is on to make these sources of energy viable.
 +
 +
=== Solar energy ===
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_77958556.jpg]][[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_4c924b2.jpg]]
+
The source of energy most readily available to us
 +
is the sun. Solar energy has several advantages over the other
 +
energy sources. It is inexhaustible; it is free from any pollution
 +
and unlike fossil fuels, transformation of solar energy does not
 +
produce any toxic by-products.
  
Energy is defined for an object in a particular
+
state. When work has been done on an object, its energy changes. At
+
Nature provides some concentration of the sun’s
a very basic level, there are two forms of energy – kinetic energy
+
energy in the form of wind and waves. The gradients set up in the
and potential energy.
+
atmosphere by solar heating turn some of its energy into the movement
 +
of large masses of air, thereby providing wind energy. This wind, in
 +
turn, whips up the waves in the sea which at places can provide
 +
highly concentrated energy. But none of these sources of energy in
 +
their natural form can as yet provide a viable alternative to the
 +
conventional sources. Therefore, global effort is on to tap energy
 +
in concentrated form from the non-conventional sources.
  
 +
 +
When solar radiation strikes the earth’s
 +
atmosphere, some of it is reflected by dust particles and clouds,
 +
some of it is absorbed by carbon dioxide, water vapour, ozone layer
 +
and the remaining reaches the earth’s surface. Most of the
 +
ultraviolet radiation is absorbed by the ozone layer. Some infrared
 +
radiation is absorbed by the ozone layer. Some infrared radiation is
 +
absorbed by clouds, carbon dioxide and water vapour. The amount of
 +
radiation, reaching the earth, thus may vary with the presence of
 +
clouds, humidity, the latitude- the position of the place north or
 +
south of equator, the time of year, the time of day and other
 +
factors. An idea of the magnitude of energy reaching the earth’s
 +
surface falling on an area equal to the size of the tennis court per
 +
day is roughly equal to the energy obtained from 135 litres of petrol
 +
or 180 kg of coal.
  
For example, a block is lying at rest on a table.
 
It is pushed and it acquires a uniform velocity. Now the block has
 
acquired some energy (kinetic energy, as we will define shortly).
 
While the cause of the change in the state was a force (the push), it
 
has resulted in the body acquiring a change in energy.
 
 
 
   
 
   
We can see that there are two ways of describing
+
=== Harnessing Solar Energy ===
this (and for that matter, any) process. One is to study the cause
+
(the force) and the other is to examine the change in energy.
+
Solar energy can be harnessed in five ways:
  
 
   
 
   
== Understanding Kinetic Energy ==
+
# using solar panels
 +
# solar thermal
 +
# concentrated solar power
 +
# solar nanowires and
 +
# By using photosynthetic and biological processes.
 
   
 
   
If an object is moved from rest to a uniform
+
However,
velocity, horizontally, it has acquired kinetic energy. Conversely,
+
before solar energy can be successfully utilized, two major problems
if an object is moving with a velocity ‘v’ and has to be stopped,
+
need to be solved. '''Firstly'''
work needs to be done. Let us understand this mathematically.
+
solar energy is highly diffused; that is, it is thinly spread over
 +
the earth’s surface and so one needs to concentrate it, '''secondly''',
 +
solar energy has to be stored for us during night or on a very cloudy
 +
day.
  
 
   
 
   
 +
When sunlight concentrated by a convex lens is
 +
made to fall on a piece of paper, it burns. The problem of
 +
concentrating solar energy may be solved through the use of different
 +
types of reflectors for focusing sunlight. Reflectors are used in
 +
solar cookers and solar ovens. The simplest of these reflectors is a
 +
single reflector provided in hot-box type of solar cookers. It is a
 +
sheet of polished looking glass or aluminized plastic hinged to one
 +
side of the box which reflects solar radiation into the cooker and
 +
heats it. In a solar oven, several reflectors are provided on all
 +
sides of a box. Curved mirrors, parabolic reflectors and Fresnel
 +
lenses are also used in solar cookers.
  
 
+
 +
=== Solar Thermal Power Generation ===
 +
 +
Generally two approaches are followed in this
 +
method of power generation
  
 
   
 
   
Let us say an object of mass ‘m’ is moving
+
(1)sunlight reflected from several mirrors
with a velocity ‘v’ and is brought to rest by a retarding force
+
arranged in an array is focused on a single heat exchanger in a solar
over a distance ‘s’
+
furnace; and
  
 
   
 
   
The
+
(2)a large number of cylindrical reflectors in a
acceleration = v<sup>2</sup>/ 2s
+
solar farm focus solar radiation on long pipes carrying a gas which
 +
collects the heat. A good example of the solar furnace approach is
 +
the tower concept. Sunlight is focused on to a boiler mounted on the
 +
top of a tower located near the centre of the field of mirrors to
 +
produce a high temperature for driving a steam turbine. Another
 +
similar plant system used arrays of heliostat-guided mirrors to focus
 +
sunlight into a cavity-type boiler near the ground to produce steam
 +
for a steam turbine electric power plant. Sunlight striking the
 +
mirrored faces of the heliostat modules is reflected and concentrated
 +
in the cavity of the heat exchanger.
  
 
   
 
   
The force required = m x a
+
In contrast to the solar furnace approach, in the
 +
solar farm, parabolic cylindrical concentrators or other types of
 +
concentrators are used to focus sunlight on to a central pipe
 +
surrounded by an evacuated quartz envelope. Heat collected by a
 +
fluid(nitrogen or helium) flowing through these pipes may be stored
 +
at a temperature over 500 degree Celsius in a molten salt. This heat
 +
may then be used to drive steam turbines for the generation of
 +
electricity
  
 
   
 
   
= m x v<sup>2</sup>/
+
=== Photovoltaic Power Generation ===
2s
 
 
 
 
   
 
   
Work done =
+
[[Image:Energy%20for%20KOER_html_m4d95859e.gif]]Unlike
force x displacement
+
the solar thermal systems discussed above, solar cells offer a very
 
+
attractive means for direct conversion of sunlight into electricity
+
with high reliability and low maintenance. The disadvantages,
= (m x v<sup>2</sup>/
+
however, are high cost and difficulty of storing large amounts of
2s) x s
+
electricity as compared with the relative ease of storing heat for
 
+
later use. The working of a solar cell depends upon the phenomenon
+
of photo electricity; that is, the liberation of electrons by light
= ½ m v<sup>2</sup>
+
falling on a body. Though this phenomenon has been known for a long
 
+
time, its application to semiconductors such as silicon has proved to
+
be of great use. The principle of solar cells is simple. When light
This is the expression of the kinetic energy that
+
waves strike a semi-conductor material with energy sufficient to
the object had.
+
dislodge an electron from a fixed position in the material and make
 +
it move freely in the material, a vacant electron position or ‘hole’
 +
is created in the material. The hole acts a positive charge and can
 +
move if a neighbouring electron leaves its site to fill the hole
 +
site. A current is created if the electron-hole pairs are separated
 +
by voltage in the cell material. Such an intrinsic voltage may be
 +
created by adding small amounts of impurities or dopants to the pure
 +
material or by joining two semiconductor materials. When impurities
 +
such as phosphorous are introduced into silicon, it becomes
 +
electron-rich and is referred to as ‘n-type’ silicon. On the
 +
other hand, impurities such as boron give rise to ‘p-type’
 +
silicon with excess of holes. When these two oppositely charged
 +
semiconductors (one electron rich and the other electron-deficient)
 +
are in contact, free charge leaks across the common boundary and
 +
becomes fixed as ions in the region adjacent to the boundary. At the
 +
interface, the fixed (but opposite) ions create an electric field
 +
that sends free electrons one way and free holes the other.
  
 
   
 
   
If this object is a car and it was brought to rest
+
In the dark, no current flows in the solar cell.
by braking, the kinetic energy was lost as heat energy due to
+
But when it is illuminated, a current will flow as long as the cell
friction (braking) between the road and the car tires. The total
+
is illuminated and can supply electricity to an external load.
energy remains conserved; it merely moves from one form to another.
 
  
 
   
 
   
== Understanding Potential Energy ==
+
The
 +
best and most efficient solar cells are constructed from high purity
 +
silicon. This type of cell has already been used very successfully
 +
for providing electrical power in spacecraft. The overall efficiency
 +
of photovoltaic cells is around 11 percent. But their cost has
 +
prevented their use for large-scale generation
 +
 
 
   
 
   
If an object is lifted from the ground to a
+
=== Conversion into Electrical Energy ===
certain height, work has been done in moving it and this is stored in
 
the object as potential energy. If the object is dropped, it will
 
fall to the ground with a velocity and will acquire kinetic energy.
 
 
 
 
   
 
   
 
+
The conversion of solar energy into electricity
 
+
can be achieved via two routes:
  
 
   
 
   
There are a few important points to keep in mind
+
(1) solar energy is
with respect to potential energy:
+
used to boil water which can then be used to generate electricity
 +
(solar thermal power generation)
  
 
   
 
   
* It is also useful to think of potential energy in terms of change in energy level with respect to a zero. The surface of the earth has been arbitrarily assumed to be at zero potential energy.
+
(2) direct conversion of solar energy into
* Potential energy can be more usefully understood and described as potential for energy. When a body has potential energy, it has the capacity to do work. When a spring is compressed, work has been done on it. If it is released, the spring can do work. The potential (for) energy that it has allows the spring to do work.
+
electricity using solar cells.
* The potential for energy is with respect to a zero defined for a system. The potential energy is, therefore, always to be referred to in terms of a system. The potential energy of the object-earth system was changed when it was lifted to a height ‘h’.
 
 
If an object of mass ‘m’ is raised to a height
 
‘h’, work has been done.
 
  
 
   
 
   
Work done = m x g xh
+
=== Wind Energy ===
 
 
 
   
 
   
= mgh
+
Wind is produced by
 +
temperature differences in the air. This is true both of a gentle
 +
evening breeze as well as a roaring hurricane. The main driving
 +
force behind the wind system of the earth’s atmosphere is the
 +
temperature difference between the tropics and the polar regions.
 +
This temperature difference arises due to the fact that the tropical
 +
regions of the earth are much warmer than the polar regions. Wind
 +
energy is the energy of air in motion and has been used for ages for
 +
driving sail boats, for grinding grain and pumping water.
  
 
   
 
   
This is stored in the object as potential energy
+
Today it is also used
and when the object falls, gets converted into kinetic energy. In
+
for generating electric power. When air is blown on wind vane, a
this particular case, the potential energy is referred to as
+
child’s common toy, starts rotating. This idea is used in making
gravitational potential energy.
+
the windmill which is nothing but a big wind vane. Wind energy is
 +
inexhaustible and is therefore a permanent source of energy as there
 +
will always be winds. According to an estimate, about 175 to 220
 +
thousand trillion watt hours per year of wind energy can be produced
 +
globally, This is a very promising figure as it is about 2.7 times
 +
the total energy used on the earth today.
  
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m2c2c5733.gif]]
+
=== Hydroelectric Power ===
 
 
 
   
 
   
== Potential Energy – Kinetic energy changes during free fall ==
+
Running water is an
+
easily available source of energy. It is available free and does not
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_6ddeba61.gif]]
+
pollute the environment. Running water can be used to burn a turbine
 +
generator to produce electricity and is the basis of the
 +
hydroelectric plant. Water is stored in a reservoir behind a dam.
 +
When water flows from a height, it turns big turbines to generate
 +
electricity.
  
 
   
 
   
== Conservation of energy ==
+
[[Image:Energy%20for%20KOER_html_cb7184a.jpg]]<br>
+
''Srisailam
The key idea here is that the total energy of the
+
Dam across the Krishna River''
system is conserved. Potential energy can be converted into kinetic
 
energy and vice versa. But the total energy remains unchanged.
 
  
+
The gravitational potential emergy of the water is converted
In more general terms, the law of conservation of
+
into kinetic energy that powers the turbines to produce electricity.
energy states that energy can neither be created nor destroyed; but
+
There are a number of hydroelectric power plants in India; the Bhakra
can be transformed from one form to another.
+
Nangal dam in punkab, Damodar valley Project in West Bengal, Hirakud
 +
Project and Kosi Project in Bihar and the Nagarjunasagar project in
 +
Andhra Pradesh to name a few. These projects produce a very
 +
significant percentage of the total electricity generated in our
 +
country. However, large dams also have a high degree of
 +
environmental impact in terms of flooding and silting of the rivers.
 +
The environmental costs of the dams must be weighed against the
 +
benefits of the dams.
  
 
   
 
   
Suppose a cart is rolling across a floor and
+
=== Ocean energy ===
strikes a box at rest on the floor. As a result of the collision,
 
the box will slide a certain distance across the floor before coming
 
to rest because of friction. The sliding box has moved against the
 
frictional force has therefore done a certain amount of work. The
 
box moved and did work because energy was supplied to it by the
 
moving cart. The energy that an object possesses by virtue of its
 
motion is called '''Kinetic energy'''. The more massive the object
 
is and the faster it moves, the greater is its KINETIC ENERGY.
 
 
 
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_2a51c40a.jpg]] A
+
Tides are the raising
bullet fired from a gun for example can piece through the body
+
and filling of the ocean level due to the moon’s gravitational pull
because it moves with a very high speed although its mass is not very
+
which can be easily seen along the seashore. It is possible to
large. If an object is lifted to a height, it acquired another form
+
extract energy from these tides and the main requirement for
of energy called '''potential energy'''. An object can also possess
+
harnessing tidal energy is that the difference between the high tide
potential energy. An object can also possess potential energy if it
+
and the low tide should be large, at least a few metres. The first
is put under strain. Then it has energy stored in it because of the
+
ever tidal powered electric generating plant was set up on River
work done to bring it in that condition. In a time piece, the main
+
Rance in France, to harness the power tides in the English Channel
spring, for example, once wound keeps unwinding and driving the
+
which rise to as much as 14 metres at this location. By opening
clockwork mechanism for many hours. Here the coiled spring has
+
gates as the tide rises and then closing them at high tide, a
energy stored in it because of the work done on it while winding.
+
23-square kilometers pool is formed behind the Rance river dam. As
 
+
the tide falls, the trapped water is allowed to flow out, driving 24
+
electricity generating turbines of 13MW capacity each for total
So far we have discussed two forms of energy
+
average power output of 310MW.
KINETIC ENERGY and POTENTIAL ENERGY. Both can manifest themselves in
 
other ways.
 
 
 
 
The molecule in every bit of matter solid, liquid
 
or gas are in a continual state of motion. This random motion of
 
molecules(or atoms) constitute an internal KINETIC ENERGY or Thermal
 
energy that an object possesses even though the object as a whole
 
may not be in motion. Thermal energy is thus manifestation of the
 
motion of the molecules of a substance. A change in the thermal
 
energy of an object can be brought about by supplying heat to the
 
object. For example, by repeatedly hitting a block of metal with a
 
hammer, its atoms are caused to move rapidly, thereby raising the
 
thermal energy of the metal block which as a result becomes hot.
 
  
 
   
 
   
When petrol burns or when dynamite explodes for
+
It is estimated that
example the potential energy stored in these substances is converted
+
the total global potential for tidal power is only2 percent of the
into heat or KINETIC ENERGY.
+
world’s potential hydroelectric capacity. Besides, it involves
 +
very high initial cost and the output is variable.
  
 
   
 
   
== Key vocabulary ==
+
=== Energy from waves ===
 
 
== Additional web resources ==
 
 
 
= Forms of energy =
 
 
   
 
   
We have discussed two forms of energy, viz,
+
Unlike the tides which
Kinetic energy and potential energy. But energy occurs in various
+
exhibit a regular but long periodic variability, waves keep the ocean
forms such as electrical energy, heat energy, solar energy tidal
+
water in continual motion. The vertical rise and fall of the
energy hydro energy, geothermal energy and so on. All these forms of
+
successive waves can be used to produce energy. India’s first wave
energy fall under the two categories of energy kinetic and potential.
+
energy project has gone on stream at vizhinjam near Trivandrum. The
 
+
150-MW project implemented by the Wave Energy Group attached to the
+
Ocean Engineering Centre, IIT, Madras, in association with the state
Potential energy is the stored energy and the
+
Harbour Engineering department. This project works works on the
energy of position. Chemical energy, nuclear energy, stored
+
principle of an oscillating water column, which drives an air
mechanical energy and Gravitational energy come under potential
+
turbine. The turbine is so designed that it rotates in one
energy.
+
direction, irrespective of the direction of air flow. It is a
 +
multipurpose scheme and floats on the sea bed. From the ecological
 +
and environment points of view too, it is the best as the unit hardly
 +
leaves any waste. The biggest advantage of the project is that power
 +
generation is possible throughout the year, though not uniformly.
  
+
       
<u>'''Chemical energy'''</u>''': C'''hemical
 
energy is the energy stored in the bonds of atoms and molecules.
 
 
 
         
 
 
{| border="1"
 
{| border="1"
 
|-
 
|-
 
|  
 
|  
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m44e5e465.jpg]]
+
[[Image:Energy%20for%20KOER_html_m550953e9.jpg]]<br>
  
 
   
 
   
 
|  
 
|  
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_76425964.jpg]]
+
[[Image:Energy%20for%20KOER_html_m44b8741.jpg]]<br>
  
 
   
 
   
|  
+
|}
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m2c5971ce.jpg]]
+
=== Energy from Ocean Thermal Gradients ===
 
 
 
   
 
   
|}
+
[[Image:Energy%20for%20KOER_html_m533a134.jpg]][[Image:Energy%20for%20KOER_html_196bef2b.jpg]]The
<u>Examples,
+
heat contained in the ocean waters heated by the sun can be converted
Biomass, petroleum, natural gas, propane and coal are stored chemical
+
into electricity by utilizing the difference in temperature between
energy.</u>
+
the surface water can be used to heat some low-boiling organic liquid
 +
such as ammonia or propane, the vapours of which are allowed to
 +
expand through a turbine which can run a generator. The vapours
 +
leaving a turbine are channeled into a condenser located in the low
 +
temperature water zone, much below the water surface. The condensed
 +
liquid is pumped into a boiler evaporator to start the cycle afresh.
  
 
   
 
   
 
+
The expected efficiency
 
+
of such a system is about 2 percent. The amount of energy available
 +
from ocean thermal gradients is enormous, and is replenished
 +
continuously.
  
 
   
 
   
<u>Nuclear
+
=== Geo thermal energy ===
energy</u>: Nuclear energy is the energy stored
 
in the nucleus of an atom. It is the energy that holds the nucleus
 
together. Example , nucleus of an uranium atom.
 
 
 
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m9e8921d.jpg]][[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m4db0caad.jpg]][[:]]
+
We are
 
+
living between two great sources of energy- the sun up in the sky,
 
+
and hot rocks beneath the earth’s surface. The interior of the
 
+
earth is extremely hot. As one goes deep into the earth the
 
+
temperature increases. The earth has very hot materials in and below
 +
the crust. As some places this hot material
 +
comes quite close to the surface, or even out of the surface in
 +
the form of volcanic eruptions. In places where it comes close to
 +
the surface, underground water often gets heated
 +
and produces steam and hot water which comes out as hot springs and
 +
geysers. The areas in which such conditions exist are known as
 +
geothermal regions. Infrared photography of the ground from
 +
satellites like IRS-1 has played an important role in locating the
 +
geothermal regions.
  
 
   
 
   
 
+
[[Image:Energy%20for%20KOER_html_m224b8bc5.jpg]]After
 
+
locating a geothermal region, a bore is drilled through the rock to
 +
tap the heat. In many places steam under high pressure comes out
 +
straight from the borehole and can be used to drive turbines
 +
directly. Where steam is not available, cold water is pumped down
 +
through one hole and heated water and steam produced pumped out of
 +
another. The hot water or steam produced can be used to run a turbine
 +
or to heat housed and offices. Geo thermal energy is used for space
 +
heating where the temperature goes down to 30 to 35 degrees below the
 +
freezing point, for poultry farming, mushroom cultivation and
 +
pashmina-wool processing which need a warmer climate.
  
 
   
 
   
 
+
Although at first
 
+
glance, geothermal energy seems very promising, geothermal sources
 +
are, in reality, far from being pollution free. Underground steam
 +
contains hydrogen sulphide gas and minerals which can poison fish and
 +
other forms of aquatic life in streams and rivers.
  
 
   
 
   
<u>'''Stored mechanical energy'''</u>: Stored
+
= Energy storage =
mechanical energy is the energy stored in the objects by the
 
application of a force. Compressed springs and stretched rubber
 
bands are examples of stored mechanical energy.
 
 
 
 
   
 
   
<u>'''Gravitational
+
We have seen that whatever the source of energy,
energy: '''</u>It is
+
all of these are converted into electrical energy for use. This
the energy of place or position. Water in a reservoir behind a
+
brings to focus the need for energy storage and distribution.
hydropower dam is an example of gravitational potential energy. When
 
the water is released to spin the turbine it becomes kinetic energy.
 
  
 
   
 
   
kinetic energy is energy in motion. It is the
+
One of the problems associated with the generation
motion of waves, electrons, atoms , molecules and substances. Radiant
+
of electricity from various is that the demand for power fluctuates.  
energy, thermal energy, motion, sound and electrical energy come
+
During the day, the power requirements, especially for commercial
under kinetic energy.
+
purposes, are much greater than during night time. If there was some
 +
way to store electrical energy, the generating plant could be
 +
operated at full capacity during the night, storing up energy to be
 +
released when the demand increases.
  
 
   
 
   
<u>'''Radiant energy: '''</u>It is the
+
== Concept flow ==
electromagnetic energy that travels in travels in transverse waves.
 
Radiant energy includes visible light, x-rays, gamma rays and radio
 
waves. Solar energy is an example of radiant energy.
 
 
 
 
   
 
   
<u>'''Thermal energy: '''</u>Thermal energy or
+
Some of the key ideas in energy storage are:
heat energy is the internal energy in substances. It is the vibration
 
of atoms and molecules within substances. Geothermal energy is an
 
example of thermal energy.
 
  
 
   
 
   
<u>'''Sound: '''</u>It is the movement of energy
+
# All forms of energy are used to generate electrical energy
through substances in longitudinal (compression/rarefaction) waves.
+
# Generation, storage and transmission of electrical energy is involved in meeting energy demands
 
+
# There are two different approaches for storing electricity energy, depending upon whether this storage is for small-scale or large-scale purposes.
 
   
 
   
<u>'''Electrical energy: '''</u>It is the
+
=== Small-scale storage ===
movement of electrons. Lightning and electricity are examples of
 
electrical energy.
 
 
 
 
   
 
   
We have seen that energy occurs in various forms.
+
[[Image:Energy%20for%20KOER_html_m7a21910d.jpg]][[Image:Energy%20for%20KOER_html_bb112d6.png]]For
These different forms of energy can be converted from one form to
+
small-scale storage of electricity, batteries and fuel cells offer
another.
+
the best course. An electric battery consists of one or more electric
 +
cells which are devices for producing electric directly from the
 +
chemical reactions. Electricity made in this way is much more
 +
expensive than that made by mechanical generators but batteries being
 +
compact and portable, are a better choice for many applications
 +
Cells are generally of two types; primary cells and secondary cells.
  
 
   
 
   
* For example, when we switch on an electric light firstly, we can see the transfer of electrical energy from the power plant to our home, and then the conversion of electric energy into heat energy, part of it into visible light. This light energy is not destroyed but it is absorbed by the walls, ceiling and floor and other objects, finally to be converted into heat.
+
One good example of a primary cell is a voltaic
* electric energy → heat energy+ light energy
+
cell which consists of copper
* In power plant, chemical energy stored in fossil fuels such as coal, oil or gas is converted into heat energy in the boiler by combustion. This heat energy changes water from liquid state to steam. This heat energy of steam is converted in part, into mechanical energy in the steam turbine. This mechanical energy is then converted into electrical energy in the generator. From the generator it is transferred by the electric cables to various points where it can be used for further transfer to homes and industries etc.,
 
* Chemical energy → heat energy → steam energy → mechanical energy electrical energy → light energy+ heat energy+ mechanical energy+ etc.,
 
* In the running of a car the chemical energy hidden in the explosive mixture of petrol vapour and air is converts by the spark into heat energy. The heat energy, in turn is converted in part, into mechanical energy of motion of the pistons in the cylinders. The mechanical energy of the pistons is transferred to the drive shaft and from there to the wheels to move the car.
 
* Chemical energy → heat energy → mechanical energy
 
* All biological processes throughout the domain of living things can also be shown to be energy conversion processes. The digestion of food is a combination of rather complicated processes but what it amounts to is the transformation of chemical energy locked in the food into heat energy to keep the body warm, and into mechanical energy to enable the body to do work by moving its various parts or itself as a whole besides synthesizing some compounds. There is also some conversion into electrical energy to establish communication between various parts of the body through the nervous system.
 
* Chemical energy → heat energy + mechanical energy + electrical energy
 
* In all the above examples energy is converted from one to another, but the total energy in any energy conservation process always remains constant; that is energy can neither be created nor destroyed. This is the law of conservation of energy.
 
 
== Key vocabulary ==
 
 
# Vibration-Any regularly repeated to and fro motion
 
# Law of conservation-A physical law that some property of a system remains constant throughout a series of changes
 
 
== Additional web resources ==
 
 
1)
 
[[http://www.youtube.com/watch?v=VJfIbBDR3e8]]
 
  
 
   
 
   
2)
+
and zinc metal plated dipped in a solution of
[[http://www.youtube.com/watch?v=f9kJwtayTJI]]
+
sulphuric acid which acts as an electrolyte. The electrolyte
 
+
contains positive and negative ions but is overall electrically
 
+
neutral. Zinc tends to dissolve in the solution more easily than
= Power, energy units and conversions =
+
does copper. In solution it forms positive zinc ions leaving
+
electrons behind on the zinc plate. This gives zinc plate a negative
One important aspect of the processes producing or
+
charge with respect to copper plate and so, when an electric circuit
using or/and converting energy from one form to another is the rate
+
is completed at the terminals of the cell, the electrons flow to the
at which this is done. For example, two persons perform equal
+
copper plate giving rise to a current. This cell becomes dead when
amounts of work by lifting identical boxes from the ground level and
+
the solution becomes saturated with zinc so that no more of it wants
keeping them on a shelf .One of them does this rapidly while the
+
to dissolve. To revive the cell one has just to replace the
other does it slowly. Although the total work done by each person is
+
electrolyte sulphuric acid, this can be continued so long as zinc is
the same, the two persons work at different power levels. The faster
+
present but when the zinc is gone, the cell is permanently dead. The
working person converts his body’s chemical energy into work at a
+
principal disadvantage of the primary cell is its short life.
more rapid rate than the slowly working person
+
Obviously it would be more useful to have a cell which could be
 +
restored to its original condition once it had discharged all its
 +
available form of energy. Fortunately it is possible to do so with
 +
some types of cells. Such cells are called secondary cells and a set
 +
of them is called a storage battery because it enables charges
 +
produced by other means to be stored for later use. In a storage
 +
battery electricity is stored where chemical changes take place which
 +
can be reversed to release the stored electrical energy. A typical
 +
storage battery takes a few hours to charge and can then be used as a
 +
source of energy.
  
 
   
 
   
Power is the rate at which work is done or energy
+
These batteries find use in the fabrication of
is used or supplied and may therefore be calculated by dividing the
+
uninterrupted power supplies for continuous operation of costly
work done (or energy used or supplied) in the process by the time
+
equipment, computers and other strategic gadgets. Here the batteries
taken by the process. Energy or work is measured in Joules (J) and
+
are coupled with an oscillator which converts this D.C supply from
time is measured is seconds (s) and so the unit of power is the '''joule
+
this battery to A. C. at higher voltage and frequency.
per second (J/s),''' This unit is given the special name '''WATT (W)'''
 
where
 
  
 
   
 
   
1watt =1 J/s
+
=== Large scale storage ===
 
 
 
   
 
   
1000watt =1
+
For meeting the large energy requirements of homes
kilowatt=1kw
+
and industry, storage batteries are impractical. To meet the
 +
requirements of varying demands, electricity generation is increased
 +
or decreased and in many cases, there is a transmission and
 +
distribution company that manages this kind of scheduling.
  
 
   
 
   
1000,000 watt =1megawatt=1MW
+
= Nuclear energy =
 
 
 
   
 
   
1,000,000,000watt =1gigawatt=1GW
+
We have seen how different sources of energy are
 +
used to generate steam and hence the mechanical energy to produce
 +
electricity. These sources can be renewable or non-renewable. Yet
 +
another source that has been used to generate electrcity is nuclear
 +
energy, the atomic energy is used in the generation of energy. In
 +
this section, we will understand the atomic structure and the source
 +
of energy in the atom.
  
 
   
 
   
1,000,000,000,000watt =1terawatt=TW
+
== Concept flow ==
 
 
 
   
 
   
A commercial unit energy that we often hear about
+
# Atoms consist of protons, neutrons and electrons. Different atoms and nuclei have different levels of stability. Atoms occur in more than one configuration due to difference in their nuclear structure and these different configurations are called isotopes.
on out electricity bills is the '''kilowatt hours (kwh).'''
+
# A vast amount of energy is available within the nucleu and nuclear reaction processes release this energy. Nuclear energy so produced is used in the place of coal or gas to heat water and produce steam. A nuclear reaction occurs when uranium atoms split intosmaller particles in a chain reaction that produces a large amount of heat.
1kilowatt hour is the energy used or supplied when 1kw power is used
+
# Chemical reactions, such as burning, involve the release of energy mainly due to exchange or transfer of electrons whereas nuclear energy involves the release of energy from within the nucleus of the atoms.
or supplied for one hour. '''1kwh is equal to 3.6 million joules'''
 
 
 
 
   
 
   
== Energy Units and conversions ==
+
=== Atoms ===
 
   
 
   
The basic unit for the measurement of energy in
+
All matter is made up of different naturally
the metric system is the joule, but there are also other units in
+
occurring elements, each possessing physical and chemical properties
common usage. The kilowatt hour is usually used to describe
+
distinct from the other. These smallest entities into which these
electrical energy. The '''calorie''' which is defined as the amount
+
elements can be divided are called atoms. Atoms are made up of three
of heat energy required to raise the temperature of 1g of water
+
still smaller particles-positively charged protons, negatively
through 1degree Celsius, is the unit primarily used to measure heat
+
charged electrons and electrically neutral neutrons. The relatively
and also to describe the energy content of foodstuf
+
heavy protons and neutrons constitute the tiny nucleus. This is
 +
surrounded by moving electrons and overall the orbit is electrically
 +
neutral and is about ten to the power of 5 times the size if the
 +
nucleus. The number of orbiting electrons is always equal to the
 +
number of protons so that the net electrical charge of the atom is
 +
Zero.
  
 
   
 
   
== Additional web resources ==
+
Atoms of a particular element always contain the
+
same number of protons and there is a scale of elements, going from
# www.sciencejoywagon.com/'''physics'''zone/05'''work'''-'''energy'''/ -
+
the atoms of hydrogen which have only one proton, helium atoms which
+
have two protons, lithium atoms which have three protons, and so on
= Sources of energy - conventional =
+
all way up to very large atoms such as uranium, which has 92 protons.
+
The number of protons is therefore, important because it identifies
Firewood has been the major source of energy
+
the element to which the atom belongs. Thus any atom which contains,
during most of man’s history and it continued to remain the most
+
say 17 protons must be chlorine; uranium atoms always contain 92
important fuel until the middle of nineteenth century. Firewood is
+
protons, and so on. The atomic number of an element is the same as
obtained from the forests and is primarily used for heating and
+
the number of protons in the nucleus.
cooking. The other fuel which has been traditionally used here is
 
animal dung cakes. The animal dung mainly consists of undigested
 
plant material which on drying, gives a product that readily burns.
 
One of the disadvantages of both firewood and animal dung cakes as
 
fuels is that they give a lot of smoke on burning. By contrast,
 
charcoal prepared by burning wood in insufficient supply of air is a
 
clean fuel and gives negligible smoke on burning. Till a few years
 
ago, charcoal was a major source of energy in urban areas. It has
 
now been largely replaced by the liquid and gaseous fuels such as
 
kerosene and petroleum gas.
 
  
 
   
 
   
The industrial revolution in Europe around the
+
[[Image:Energy%20for%20KOER_html_m2a27ed59.gif]]Along
middle of the nineteenth century led to search for other fuels to
+
with the protons in the atomic nucleus there are also the
meet the increasing energy demands. The discovery of coal, followed
+
electrically neutral particles called neutrons. The number of
by oil and natural gas fulfilled these demands to a large extent and
+
neutrons in the nucleus tends to increase with number of protons.
these fuels since then have been the primary sources of world’s
+
For instance, in the helium atom ( which has two protons) there are
energy. All these chemical fuels-coals, oil and natural gas- are
+
two neutrons, lithium (which has three protons) has four neutrons,
derived from the slow decay of living organisms such as trees, algae
+
uranium (which has 92 protons) has 146 neutrons, and so on. The
and small marine animals for millions of years and are therefore
+
protons and neutrons in a nucleus are bound together by immensely
known as fossil fuels. The fossil fuels are being consumed at an
+
strong forces, called nuclear forces which counteract the
appreciable rate. The fossil fuels are being consumed at an
+
electrostatic forces of repulsion acting between the protons. In
appreciable rate. Although their new deposits continue to be
+
very large atoms, such as uranium and plutonium, the binding nuclear
discovered, the world reserves of these fuels are not limited.  
+
forces are only slightly stronger than the repulsive forces between
Further, these energy sources take millions of years to form and
+
the large number of protons; such nuclei are unstable and can be made
therefore fossil fuels are also known as non-renewable sources of
+
to undergo fission- split into two or more fragments releasing
energy. These fuels once exhausted cannot be replaced quickly when
+
nuclear energy.
exhausted. Hence these are also called as exhaustible resources.
 
 
 
 
== Formation of fossil fuels ==
 
 
Fossil fuels-coal, oil and natural gas-are the
 
result of decomposition of living matter. Coal is obtained from dead
 
plant matter which consists primarily of carbon, hydrogen and oxygen.
 
  
 
   
 
   
On dry land, this matter rots away by bacterial
+
=== Isotopes ===
action in presence of atmospheric oxygen to form carbon dioxide and
 
water. But in swampy locations, the dead plant matter is covered
 
with water and is, therefore, protected from the oxidising action of
 
air. Instead, it is attacked by bacteria which do not require free
 
oxygen in order to live. In the process oxygen and hydrogen of the
 
dead plant matter gradually escape and the residue, therefore,
 
becomes richer and richer in carbon. The end product of the
 
bacterial action is a soggy, carbon-rich substance called peat.
 
 
 
 
   
 
   
Over long periods of time the peat is covered
+
The atomic weight of an element is expressed as
with sand, silt and clay. As peat gets compressed and heated further
+
the sum of the number of protons and neutrons. Atoms of the same
due to geological changes, more gases are forced out and therefore
+
element can differ from one another by having a different number of
the proportion of carbon continues to increase. In this way, peat is
+
neutrons in their nuclei. For example, uranium (which has 92
gradually converted into various forms of coal such as lignite,
+
protons) can have either 143 or 146 neutrons. These two forms of
bituminous coal and anthracite.
+
uranium have the same chemical but slightly different physical
 +
properties. Atoms of the same element which exist in different forms
 +
as a result of having different numbers of neutrons in their nuclei
 +
are called isotopes. The first of the two uranium isotopes described
 +
above is called uranium-235, and the second, uranium-238.
 +
Uranium-238 is heavier than uranium-235. Similarly there are three
 +
isotopes of hydrogen, namely hydrogen (one proton only), deuterium or
 +
heavy hydrogen ( one proton and one neutron), and tritium ( one
 +
proton and two neutrons).
  
 
   
 
   
In contrast to coal, the raw material in the
+
Atoms of the same element always contain the same
formation of oil and natural gas consists mainly of marine organisms,
+
number of protons in their nuclei. The number of protons is balanced
mostly plants that grow near the surface of the sea. When these
+
by an equal number of electrons to make the atom electrically
organisms die and accumulate in basins, where the water is stagnant,
+
neutral. It is the number of orbiting electrons that determines the
they are also protected from atmospheric oxidation. The dead marine
+
chemical properties of an element. When atoms combine with other to
matter is decomposed by anaerobic bacteria. Oxygen, nitrogen and
+
form molecules, there is rearrangement of the outermost electrons in
other elements escape leaving mainly compounds of carbon and hydrogen
+
the orbit ( also called valence electrons). In this process, energy
called hydrocarbons. The accumulating covering layer of sediments
+
can be stored or released so that is some reactions ( burning for
provides heat and pressure that convert the hydrocarbon material into
+
example) heat energy is released. Thus atoms of carbon ( coal, on
droplets of liquid oil and bubbles of natural gas. As more
+
combination with atoms of oxygen from the air to form carbon dioxide
sedimentary deposits are laid down over periods of time, the pressure
+
in the process of burning, release energy.
increases and the oil and gas are forced into nearby porous sand or
 
sandstone. Gradually the oil and gas migrate upward through the sand
 
and they then either escape to the surface or are trapped beneath
 
layers of clay stone. This migration process separates the oil from
 
underground water because water molecule readily adhere to sand
 
whereas oil molecules do not. Thus the oil tends to collect in the
 
pore spaces of sandy rocks beneath roof rocks with natural gases on
 
the top.
 
  
 
   
 
   
== Processing of coal and petroleum ==
+
=== Principle of Nuclear Fission ===
 
   
 
   
Coal, which is essentially pure carbon, is chiefly
+
[[Image:Energy%20for%20KOER_html_m4cc0b6df.jpg]]Isotopes
used as a combustion fuel. The reaction of carbon with atmospheric
+
of certain very heavy atoms, for example, uranium-235 and
oxygen to produce carbon dioxide is an exothermic reaction that
+
plutonium-239, are so unstable that they can be made to split
releases about 7,840 kilocalories/kg of carbon and this reaction is
+
(fission) when hit by a neutron. When this happens, a very large
responsible for the heat energy derived from burning coal. Burning
+
amount of energy is released. This process is known as nuclear
of coal produces large quantities of fly ash and noxious gases such
+
fission. In this process, the mass of the two smaller atoms (
as a sulphur dioxide and related compounds which cause atmospheric
+
collectively known as fission products) plus the mass of the two or
pollution. Coal is therefore converted into a cleaner fuel, coke, by
+
three neutronsa that are produced, is slightly less than the mass of
heating crushed coal to high temperatures in the absence of air.
+
the original uranium-235 or plutonium-239 atom plus the bombarding
 +
neutron. Thus, in the process of nuclear fission, some matter is
 +
lost and converted into energy. According to Einstein’s famous
 +
equation, even a small amount of matter is equivalent to a very large
 +
amount of energy. Thus the nuclear fission of uranium-235 contained
 +
in 1 tonne of natural uranium is equivalent in electricity output to
 +
the burning of approximately 20,000 tonnes of coal. Natural uranium
 +
contains only 0.7 percent of uranium-235.
  
 
   
 
   
Coal can also be converted into liquid and gaseous
+
== Fission Nuclear Reactors ==
fuels which can partially replace the fuels derived from petroleum.
+
 +
A nuclear reactor is a device in which the nuclear
 +
fission process is carried out under controlled conditions. The
 +
basic fuel of a nuclear reactor is uranium, obtained from ores such
 +
as pitchblende. Natural uranium is a mixture of two isotopes,
 +
uranium-235 and uranium 238, present in the ratio of 0.7:99. Only
 +
the comparatively rare isotope uranium-235 undergoes nuclear fission.
  
 
   
 
   
Unlike coal and natural gas which can be used
+
There are two types of nuclear reactors:
directly as fuels without processing, petroleum or crude oil is not
 
directly usable. The name ‘petroleum’ is derived from the Latin
 
words ''petra'' meaning ‘rock’ and ''oleum''
 
meaning ‘oil’. Therefore, it means rock oil, to distinguish it
 
from animal or vegetable oils. Petroleum, also often called crude
 
oil, is a mixture of hundreds of hydrocarbon compounds together with
 
small amounts of compounds of other elements. The exact composition
 
of a crude depends upon many factors such as its age and the types of
 
organisms from which it is formed. So, every deposit of crude oil
 
is a unique mixture whose exact composition differs even from
 
deposits separated from it vertically or horizontally by a few metres
 
of rock. Natural gas is normally associated with crude oil. It is a
 
mixture of gaseous hydrocarbons, mainly methane and ethane. The
 
non-hydrocarbon compounds present in crude oil are mainly compounds
 
of sulphur, nitrogen and oxygen. Other elements present in very
 
small amounts include vanadium, nickel, chlorine, arsenic and lead.
 
  
 
   
 
   
=== Detection of Oil ===
+
# '''Thermal reactors''' use uranium as fuel and have moderators to slow down neutrons. They are called thermal reactors because they use slow-moving or thermal neutrons.
 +
# '''Fast breed reactors: '''Since 99.3 percent of natural uranium is uranium-238 and since this isotope cannot undergo fission, thermal reactors are able to use a very small proportion of natural uranium. However, fast reactors are able to convert this otherwise unusable uranium-238 into a new element, plutonium-239, which can then be fissioned to liberate energy. Fast breeder reactors do not need a moderator as fast neutrons used.
 +
 +
=== Thermal reactors ===
 
   
 
   
The method generally used for locating oil
+
The core of a thermal has five components. Uranium dioxide pellets are
deposits is the seismic survey. Shock waves generated by surface
+
packed in long metal tubes known as fuel elements. A nuclear reactor
explosive charges travel through rock layers and are reflected back
+
contains several tones of uranium in thousands of fuel elements.  
by various geological structures and possible locations where oil
+
Periodically, the used-up fuel elements are taken out and new fuel
might be trapped can be found. To find whether oil is really present
+
elements put in. The most commonly used moderators used moderators
and whether it can be economically extracted, it is necessary to
+
are water, heavy water, and graphite.
drill a well.
 
  
 
   
 
   
=== Extraction and refining of Oil ===
+
Control rods are used to control the rate of the
+
nuclear chain reaction. They are made of boron which readily absorbs
Once the oil has been found by drilling the well,
+
neutrons. When these rods are lowered into the core (containing fuel
the next step is to operate the well; that is, to raise the oil to
+
elements and the moderator), that absorb most of the neutrons and so
the surface. After extraction, the oil is usually transported to a
+
there can be no chain reaction. This effectively shuts down the
refinery through pipelines. From offshore platforms, the oil is
+
reactor. As they are pulled out progressively, neutrons are
sometimes transported to the shore in large tankers. The natural gas
+
available to split uranium atoms, thus releasing more neutrons. The
produced in the process is also transported by large pipelines.
+
further the control rods are pulled out, the larger is the number of
 +
fissions in the core and more heat is produced.
 +
 
 +
 +
Since the uranium fuel as well as the fission
 +
products are intensely radioactive, a very thick steel-and-concrete
 +
shield is required to prevent the escape of any radiation from the
 +
core. Indian reactors usually have double shielding to further
 +
minimize any risk.
  
 
   
 
   
Crude oil is processed in a refinery by fractional
+
To remove the heat produced by nuclear fission in
distillation. This process involves heating the crude oil in a tall
+
the fuel elements, a coolant is used which circulates through spaces
tower so that various components are distilled out of it and can be
+
between the fuel elements, Indian reactors, which use natural
trapped at various levels in the tower. In this process the use is
+
uranium as fuel, use heavy water as coolant, but reactors using
made of the fact that the different hydrocarbon compounds in the
+
enriched uranium (in which the percentage of uranium-235 is raised by
crude have different boiling points and hence can be separated at its
+
complex processes) use ordinary water as coolant. The heated coolant
boiling point. The lightest compounds such as gases which have low
+
coming out of the core transfers the heat exchanger to boil water and
boiling points rise to the top and the heavier oils with higher
+
raise steam which is then used to run a turbine generator to generate
boiling points are collected lower down.
+
electricity.
  
 
   
 
   
The various fractions may then be further
+
=== Fast breed reactors ===
processed by cracking or refining, both of which involve the use of
+
catalysts-substances which facilitate the chemical reactions without
+
Thermal reactors are able to release energy from
themselves undergoing any change. Catalytic cracking, often called
+
the small proportion of uranium-235 contained in the natural uranium.
cat-cracking, is a means of breaking down the heavier distillates to
+
They are, however, unable to use the uranium-238 which constitutes
form lighter compounds.
+
99.3 percent of natural uranium. The significance of fast reactors
 +
is that they are able to convert Uranium-238 into plutonium-239 in
 +
significant quantities, so that much into plutonium-239 in
 +
significant quantities, so that much more energy can be extracted
 +
from natural uranium than is possible with thermal reactors.
  
 
   
 
   
The various fractions obtained after refining are
+
There are two important features of fast breeder
used for different purposes The gas fraction, like natural gas, is
+
reactors. Firstly, there is no moderator. The neutrons given off in
used chiefly as a fuel for heating. Petrol is used in spark ignition
+
the fission reaction are not slowed down. ( It is for this reason
internal combustion engines that require a fairly volatile fuel.
+
that this type of reactor is known as a fast reactor.
Kerosene is used as a lighting and cooking fuel in villages, and also
 
in tractors and jet engines. Diesel is used in diesel engines.
 
  
 
   
 
   
=== Biomass Energy ===
+
Secondly, the fuel elements of fast reactors
+
contain a mixture of plutonium-239 and uranium-238. Plutonium is
Fossil fuels are derived from plants, trees and
+
placed in the centre of the core, whereas the uranium-238 is located
animals that lives millions of years ago. It took the remains of
+
in a blanket surrounding the plutonium core. Two processes take
these organisms millions of years of burial under tremendous pressure
+
place simultaneously in these reactors:
and the internal heat to turn into coal, oil, or gas that we use as
 
fuel today. We cannot get fossil fuels from the plant and animal
 
waste that we produce today. But they, too form a substantial source
 
of energy in the form of biomass. Biomass means the waste material
 
and dead parts of living objects. It includes garbage, industrial
 
waste, crop residue, sewage and plant waste such as dead leaves and
 
wood. These wastes can be both wet and dry. Wet wastes are in the
 
form of animal excreta or domestic and industrial residues. Dry
 
wastes refers to leaves, wood, paper, straw, fruit skin and others.
 
There are two ways of using biomass as a source of energy. One is to
 
burn the dry biomass directly to produce heat and generate steam.
 
Another method is to convert this biomass into gaseous fuels called
 
biogas by fermentation.
 
  
 
   
 
   
The raw material used for the production of
+
(i)Plutonium-239 (originally produced from some of
biogas is cow dung mixed with water which is taken in an insulated,
+
the uranium-238 atoms) in thermal reactors is fissioned, producing
air-tight container called digester. In the digester, bacteria break
+
heat which is removed by the coolant. Since the heat produced in the
the raw material into simpler chemicals by a process known as
+
core is very large, the coolant used in a fast reactor is liquid
anaerobic decomposition. Other bacteria then convert the chemicals
+
sodium.
into a biogas for fuel. The gas consists of mainly methane and is
 
drawn out through a gas outlet pipe.
 
  
 
   
 
   
Wet wastes from household and industries too can
+
(ii)A significant proportion of uranium-238 is
be used to produce methane gas. Wastes may be dumped in deep pits.
+
converted into plutonium in the blanket. In fact more plutonium is
Wells are then drilled down into the waste. A pipeline is then
+
bred in the blanket than is fissioned in the core, and for this
drilled down into the waste. A pipeline is then to recover the gas
+
reason, fast reactors are known as fast breeder reactors.
produced by the natural decomposition of the material.
+
Plutonium-239 atoms are created when uranium-238 atoms absorb fast
 +
moving neutrons.
  
 
   
 
   
=== Direct conversion of heat to electricity ===
+
=== Spent fuel ===
 
   
 
   
The most convenient usable form of energy is
+
In both thermal and fast reactors, the spent fuel
electricity. In the conventional thermal power
+
elements contain three types of material: (i)highly radioactive
 
+
fission products; (ii)large amounts of unused uranium-238, known as
+
‘depleted’ uranium; and (iii) a certain among of plutonium. By
Generation systems, heat energy from combustion of
+
reprocessing the fission products from spent fuel, the plutonium and
fuel is used to boil water to produce steam. The kinetic energy of
+
depleted uranium can be fabricated into new fuel elements for fast
steam is converted into mechanical energy in a steam turbine.
+
reactors. By repeated processes through fast reactors followed by
Finally, the mechanical energy of turbine is converted into
+
reprocessing, it is possible to extract much more energy than when
electricity in generators. These stages involve various losses and
+
using only thermal reactors. 1 tonne of natural uranium fissioned in
therefore the overall efficiency of these plants is never more than
+
a thermal reactor is equivalent to about 20,000 tonnes of coal. Used
40 percent. It is, however, possible to cut short the above energy
+
in fast reactors, however, 1 tonne of natural uranium is equivalent
conversion stages and convert heat from the combustion of fuels
+
to about 1,000,000 tonnes of coal.
directly into electricity using a magneto-hydro dynamic generator,
 
popularly known as MHD generator, which works on the basic phenomenon
 
of electromagnetic induction.
 
 
 
 
== Key vocabulary ==
 
 
 
== Additional web resources ==
 
 
# www.technologystudent.com/energy1/less4.htm - [[Cached]] - [[Similar]]
 
# [[http://video.nationalgeographic.com/video/player/environment/energy-environment/alternative-energy.html]]
 
 
= Sources of energy - Non conventional =
 
 
The conventional sources of energy discussed in
 
the previous chapter are exhaustible and cannot be quickly replaced
 
when exhausted. It takes millions of years for these sources to be
 
formed from the decay of living organisms. These sources are,
 
therefore, also known as non-renewable sources of energy. In
 
contrast, we have another class of the sources such as the sun, wind,
 
waves, tides, and geothermal heat which are inexhaustible. These
 
sources of energy are, therefore, known as renewable sources of
 
energy. A major problem in harnessing these sources of energy is
 
that the energy released by them is highly diffused as compared with
 
the energy obtained from fossil fuels or nuclear fuels. Nature
 
provides some concentration of the sun’s energy in the form of wind
 
and waves. The gradients set up in the atmosphere by solar heating
 
turn some of its energy into the movement of large masses of air,
 
thereby providing wind energy. This wind, in turn, whips up the
 
waves in the sea which at places can provide highly concentrated
 
energy. But none of these sources of energy in their natural form
 
can as yet provide a viable alternative to the conventional sources.
 
Therefore, global effort is on to tap energy in concentrated form
 
from the non-conventional sources.
 
  
 
   
 
   
== Solar energy ==
+
=== Nuclear Fusion ===
 
   
 
   
The source of energy most readily available to us
+
What is happening inside the sun?
in the sun. Solar energy has several advantages over the other
 
energy sources. It is inexhaustible; it is free from any pollution
 
and unlike fossil fuels, transformation of solar energy does not
 
produce any toxic by-products.
 
  
 
   
 
   
Sunlight is a mixture of light of various
+
[[Image:Energy%20for%20KOER_html_m413290ce.jpg]]The
wavelengths which we can see as the visible colours-violet, indigo,
+
sun consists mainly of hydrogen gas. The atoms of hydrogen under
blue, green, yellow, orange and red, wavelengths each of different
+
tremendous pressure at the centre of the sun, come together and fuse
energy. Investigations with sophisticated detectors, more sensitive
+
to for helium nucleus along with the liberation of tremendous energy
than our eyes, indicate that besides visible radiation in sunlight,
+
in the form of heat and light. It this energy which maintains its
there are two other types of radiations, namely, infrared and
+
temperature and makes the sun shine. In this process again, like in
ultraviolet radiations. These radiations, however, cannot be seen.  
+
nuclear fission, mass is converted into energy. This is also the
Ultraviolet radiation has more energy than infrared radiation.  
+
principle on which the hydrogen bomb is based. Since the various
Ultraviolet radiation causes sunburns. It also helps in making
+
reactions taking place inside the sun occur at very high
vitamin D in our skin. Infrared radiation, on the other hand, warms
+
temperatures, they are called thermonuclear reactions. The sun,
our body; that is why we feel warmer in sunlight.
+
therefore, may be considered as a thermonuclear furnace where
 +
hydrogen atoms are continuously being fused into helium atoms. Mass
 +
lost during these fusion reactions Is converted into energy.
  
 
   
 
   
When solar radiation strikes the earth’s
+
There are several possible reactions in which
atmosphere, some of it is reflected by dust particles and clouds,
+
light atoms can fuse to form heavier nuclei and release energy, but
some of it is absorbed by carbon dioxide, water vapour, ozone layer
+
the one which the scientists which have been trying to accomplish is
and the remaining reaches the earth’s surface. Most of the
+
the thermonuclear reaction involving deuterium and tritium nuclei and
ultraviolet radiation is absorbed by the ozone layer. Some infrared
+
not hydrogen nuclei. This is due to the fact that though ordinary
radiation is absorbed by the ozone layer. Some infrared radiation is
+
hydrogen is the raw material for the thermonuclear process in the
absorbed by clouds, carbon dioxide and water vapour. The amount of
+
sun, its reaction rate is quite slow. Reactions involving deuterium
radiation, reaching the earth, thus may vary with the presence of
+
nuclei or deuterium and tritium nuclei are more efficient. Fusion of
clouds, humidity, the latitude- the position of the place north or
+
two nuclei of deuterium of deuterium forms a tritium and a hydrogen
south of equator, the time of year, the time of day and other
+
nuclei while the fusion of a deuterium and a tritium nuclei forms a
factors. An idea of the magnitude of energy reaching the earth’s
+
helium nucleus with two protons and two neutrons.
surface falling on an area equal to the size of the tennis court per
 
day is roughly equal to the energy obtained from 135 litres of petrol
 
or 180 kg of coal.
 
  
 
   
 
   
=== Harnessing Solar Energy ===
+
For the above reactions to take place, the
 +
colliding deuterium nuclei should have enormous speed. This is made
 +
possible by heating the particles to a few hundred million degrees.
 +
Remember, much below this temperature, the atoms are already stripped
 +
of their electrons. Thus they form a mixture of positively charged
 +
ions and electrons known as plasma.
 +
 
 
   
 
   
Solar energy can be harnessed in five ways:
+
If one can fuse all the nuclei in 1 gram of
 +
deuterium, it would yield 100,000 kWh of energy. A complete fission
 +
of an equivalent amount of uranium, on the other hand will give
 +
25,000kWh.
  
 
   
 
   
# using solar panels
+
=== Fusion Reactors ===
# solar thermal
 
# concentrated solar power
 
# Solar nanowires and
 
# By using photosynthetic and biological processes.
 
 
   
 
   
However,
+
Despite its tremendous potential there are many
before solar energy can be successfully utilized, two major problems
+
technical problems in building a practical fusion reactor. One major
need to be solved. '''Firstly'''
+
problem is the confinement and control of plasma at more than a
solar energy is highly diffused; that is, it is thinly spread over
+
hundred million degrees so that thermonuclear energy could be made
the earth’s surface and so one needs to concentrate it, '''secondly''',
+
available at a steady rate. One very successful method to confine
solar energy has to be stored for us during night or on a very cloudy
+
the plasma in a magnetic field.
day.
 
  
 
   
 
   
When sunlight concentrated by a convex lens is
+
Among other alternatives being tried for
made to fall on a piece of paper, it burns. The problem of
+
harnessing nuclear fusion is one by using lasers. A laser is a
concentrating solar energy may be solved through the use of different
+
highly powerful beam of coherent beam of coherent light which can be
types of reflectors for focusing sunlight. Reflectors are used in
+
focused on a very small spot. In this method, called inertial
solar cookers and solar ovens. The simplest of these reflectors is a
+
fusion, pellets of deuterium-tritium fuel are rapidly compressed and
single reflector provided in hot-box type of solar cookers. It is a
+
heated by bombardment with laser beams, resulting in a series of
sheet of polished looking glass or aluminized plastic hinged to one
+
miniature thermonuclear explosions and production of energy.
side of the box which reflects solar radiation into the cooker and
+
 
heats it. In a solar oven, several reflectors are provided on all
 
sides of a box. Curved mirrors, parabolic reflectors and Fresnel
 
lenses are also used in solar cookers.
 
 
 
 
   
 
   
=== Heating for House and buildings ===
+
One of the most serious problems in the nuclear
+
fusion process is the fact that large amounts of tritium is only
One of the most promising applications of solar
+
weakly radioactive, its chemical behavior is exactly the same as
energy during the last few decades has been the heating and cooling
+
ordinary hydrogen and it can readily enter into organic substances.  
of residential and commercial buildings. Typical home solar heating
+
Control of tritium will be one of the major problems in the operation
system is shown schematically in the fig. Solar radiation falls on a
+
of the fusion reactors.
collector which is placed on the south facing slope of the roof.
 
Heat from the hot water is used to heat air. When heat is required
 
in the house , a fan forces warm air throughout the house. If the
 
water temperature in the reservoir is not sufficiently high to
 
provide adequate heating, auxiliary electrical heating may be used to
 
heat the water. During extremely cold conditions, especially on
 
cloudy days, a large amount of auxiliary heating is required.
 
Therefore, on an average, about one-third to one half of the
 
necessary heat could be supplied by solar radiation. Solar therefore
 
offers the possibility of substantial savings in fuel costs.
 
  
 
   
 
   
=== Conversion into Electrical Energy ===
+
There are many advantages of fusion power. The
+
fuel supply is plentiful and relatively inexpensive.
The
 
conversion of solar energy into electricity can be achieved via two
 
routes:
 
  
 
   
 
   
(1)solar
+
The world’s oceans constitute an inexhaustible
energy is used to boil water which can then be used to generate
+
source of the primary fuel deuterium in the form of water; about one
electricity (solar thermal power generation)
+
molecule out of every 3,000 water molecules contains an atom of
 +
deuterium. The products of fusion reactions are either stable
 +
isotopes or they are only weakly radioactive. Radioactivity will
 +
also be produced by the neutrons released in the reactions when they
 +
are captured in the materials of the reactor.
  
 
   
 
   
(2)direct
+
Further, fusion reactors do not produce air
conversion of solar energy into electricity using solar cells.
+
pollutants that contribute to acid rain or global warming. Despite
 
+
these advantages, however, immense difficulties are yet to be
+
overcome before energy generation can become feasible on a large
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_25b465a0.jpg]][[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_521ac395.jpg]]
+
scale.
  
=== Solar Thermal Power Generation ===
 
 
   
 
   
Generally two approaches are followed in this
+
The process of nuclear fission involves the
method of power generation
+
splitting of a heavy nucleus while the nuclear fusion is the joining
 +
together of lighter atoms to form heavier ones. Both the processes,
 +
however, release tremendous amounts of energy.
  
 
   
 
   
(1)sunlight reflected from several mirrors
+
= Energy and the environment =
arranged in an array is focused on a single heat exchanger in a solar
 
furnace; and
 
 
 
 
   
 
   
(2)a large number of cylindrical reflectors in a
+
Modern society cannot exist without the production
solar farm focus solar radiation on long pipes carrying a gas which
+
and utilization of energy. Every month we have to pay direct charges
collects the heat. A good example of the solar furnace approach is
+
for use of electricity. Oil and gas in our homes and for the petrol
the tower concept. Sunlight is focused on to a boiler mounted on the
+
used in our cars. And there are also indirect charges that we pay
top of a tower located near the centre of the field of mirrors to
+
for the energy used in manufacturing processes and for the
produce a high temperature for driving a steam turbine. Another
+
transportation of the goods that we buy. In addition to these
similar plant system used arrays of heliostat-guided mirrors to focus
+
charges, we pay also in terms of the effects that energy production
sunlight into a cavity-type boiler near the ground to produce steam
+
and energy utilization have on our world in terms of environment
for a steam turbine electric power plant. Sunlight striking the
+
pollution. Environmental pollution may be defined as the unfavorable
mirrored faces of the heliostat modules is reflected and concentrated
+
alteration of our surroundings. It may not be possible to estimate
in the cavity of the heat exchanger.
+
monetary losses or many of the side effects associated with energy
 +
production and energy utilization. What is the value of the health
 +
impairment, for example, caused by the cars exhaust fumes? What value
 +
do we place on the destruction of farmland and pollution of water
 +
caused by strip mining for coal? What value is associated with the
 +
loss of seaside beaches because of oil pills washing ashore? As a
 +
matter of fact, as long as we continue to produce and utilize energy,
 +
we will have to pay for these undesirable side effects. How much are
 +
we willing to pay?
  
 
   
 
   
In contrast to the solar furnace approach, in the
+
== Concept flow ==
solar farm, parabolic cylindrical concentrators or other types of
 
concentrators are used to focus sunlight on to a central pipe
 
surrounded by an evacuated quartz envelope. Heat collected by a
 
fluid(nitrogen or helium) flowing through these pipes may be stored
 
at a temperature over 500 degree Celsius in a molten salt. This heat
 
may then be used to drive steam turbines for the generation of
 
electricity
 
 
 
 
   
 
   
=== Photovoltaic Power Generation ===
+
# Uncontrolled energy consumption places a strain on the environment
 +
# Mining for coal and drilling for petroleum leads to destruction of land, pollution and habitat loss
 +
# What are the ecological costs of oil spills, health lost and other such effects?
 +
# There needs to be a judicious use of energy
 +
 +
=== Threats from Fossil fuels ===
 +
 +
Most of the energy that is generated throughout
 +
the world at present is derived from the burning of fossil
 +
fuels-coal, natural gas and petroleum products. There are numerous
 +
environment problems associated with the extraction, transportation
 +
and utilization of fossil fuels.
 +
 
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m4d95859e.gif]] Unlike
+
The most plentiful fuel source in the world is
the solar thermal systems discussed above, solar cells offer a very
+
coal. The highest quality coal(anthracite generally occurs
attractive means for direct conversion of sunlight into electricity
+
sufficiently far underground to require high-cost deep-mining
with high reliability and low maintenance. The disadvantages,
+
techniques. Further, anthracite generally contains a very high
however, are high cost and difficulty of storing large amounts of
+
percentage of sulphur and it cannot be used as a fuel without
electricity as compared with the relative ease of storing heat for
+
expensive treatment to remove sulphur. Consequently in recent years,
later use. The working of a solar cell depends upon the phenomenon
+
there has been increased interest in the mining of lower quality but
of photo electricity; that is, the liberation of electrons by light
+
relatively sulphur-free coal that lies close to the surface.
falling on a body. Though this phenomenon has been known for a long
+
Strip-mining techniques are used for the extraction of this coal.  
time, its application to semiconductors such as silicon has proved to
+
Strip mining for coal causes serious and continuing environmental
be of great use. The principle of solar cells is simple. When light
+
problems. One of the most serious problems associated with the
waves strike a semi-conductor material with energy sufficient to
+
strip-mining of coal is the huge amount of land that is torn up in
dislodge an electron from a fixed position in the material and make
+
the process. Unless rehabilitation measures are taken, the area
it move freely in the material, a vacant electron position or ‘hole’
+
adjoining the strip mined land can suffer from landslides, erosion
is created in the material. The hole acts a positive charge and can
+
and sedimentation.
move if a neighbouring electron leaves its site to fill the hole
 
site. A current is created if the electron-hole pairs are separated
 
by voltage in the cell material. Such an intrinsic voltage may be
 
created by adding small amounts of impurities or dopants to the pure
 
material or by joining two semiconductor materials. When impurities
 
such as phosphorous are introduced into silicon, it becomes
 
electron-rich and is referred to as ‘n-type’ silicon. On the
 
other hand, impurities such as boron give rise to ‘p-type’
 
silicon with excess of holes. When these two oppositely charged
 
semiconductors (one electron rich and the other electron-deficient)
 
are in contact, free charge leaks across the common boundary and
 
becomes fixed as ions in the region adjacent to the boundary. At the
 
interface, the fixed (but opposite) ions create an electric field
 
that sends free electrons one way and free holes the other.
 
  
 
   
 
   
In the dark, no current flows in the solar cell.
+
Unlike coal, the extraction of oil does not
But when it is illuminated, a current will flow as long as the cell
+
desecrate the land the way the strip-mining does. However, the most
is illuminated and can supply electricity to an external load.
+
serious environmental problem associated with oil-well drilling
 +
occurs at offshore sites. Because of the many technical difficulties
 +
inherent in offshore drilling, if a rupture occurs or if the drilling
 +
opens a crack in the rock that contains the oil deposit, a major
 +
leakage of oil into the water can occur before the damage is repaired
 +
or the crack is sealed. The release of large amounts of oil into the
 +
water can be injurious to the marine life. When the oil spreads over
 +
water, the diffusion of oxygen into water is inhibited. This affects
 +
the respiration of fish and other marine life. Oil pollution of sea
 +
causes either problems too. Oil is pushed to the shore by the water
 +
currents and winds, thereby spoiling the beaches.
  
 
   
 
   
The best and most efficient solar cells are
+
=== Combustion of fuel ===
constructed from high purity silicon. This type of cell has already
 
been used very successfully for providing electrical power in
 
spacecraft. The overall efficiency of photovoltaic cells is around
 
11 percent. But their cost has prevented their use for large-scale
 
generation
 
 
 
 
   
 
   
=== Power from space ===
+
The burning of fossil fuels releases a variety of
+
noxious gases and particulate matter into the atmosphere. The major
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_28a8f203.jpg]]A
+
contributors to this atmospheric pollution are coal and oil and
new concept of placing a large array of solar powered photovoltaic
+
natural gas by far is the least offensive of the fossil fuels , One
devices on manmade earth-circling satellites and transmitting the
+
of the major problems with coal and oil is the presence of sulphur.  
power to earth has been proposed and is receiving increasing
+
Depending upon the source, the sulphur content can be up to several
attention as a potential energy resource for the next century. The
+
percent and upon combustion several oxides (particularly sulphur
idea is that solar panels put up in space would receive on the
+
dioxide) are produced. When sulphur dioxide is released into the
ground. And this energy would be available round the clock. The
+
atmosphere, it combines with water vapour and forms sulphuric acid.  
energy thus tapped may be transmitted to the earth in a sufficiently
+
It is this sulphuric acid which is injurious to plant and animal
narrow microwave beam using a transmitting antenna. On the earth the
+
life. It has been found that atmospheric sulphuric acid eating the
energy beam may be received by a receiving antenna and converted into
+
limestone facings of many monuments and public buildings in urban
commercial frequency electric power.
+
life. Sulphur dioxide is believed to cause cough, shortness of
 
+
breath and spasm of the larynx. It can cause acute irritation to the
+
membranes of the eyes resulting in excessive flow tears and redness.
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_56745c9d.jpg]]
+
When absorbed by plants beyond a certain level the plants cells
 
+
become inactive and are killed, resulting in tissue collapse and
=== Biological conversion of Solar energy ===
+
drying of leaves. Sulphur dioxide is also known to interfere with
+
the respiratory and photosynthesis in plants.
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_2c8b489d.jpg]]
 
 
 
  
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_77206083.jpg]]
+
[[Image:Energy%20for%20KOER_html_m798592ab.gif]]The
 
+
burning of petrol in internal combustion engines is the major source
 +
of carbon monoxide, nitrogen dioxides and hydrocarbons in the
 +
atmosphere. In addition, there are large quantities of lead which
 +
are released into the atmosphere from high octane petrol used in
 +
cars. All these pollutants and the products of the photochemical
 +
reactions they undergo in presence of sunlight contribute to the
 +
noxious known as smog. There seems at present no escape from the
 +
health hazards of smog until some effective way is found to remove
 +
the pollutants from the vehicular exhaust gases.
  
 
   
 
   
Photosynthesis in plants is a biological process
+
==== Combustion of fuel - Effects of carbon Dioxide and carbon Monoxide: ====
by which they convert solar energy into sugars and starches, which
+
are energy-rich compounds. Fast growing trees having high
+
The consumption of oxygen and the
photosynthetic efficiency can therefore be harvested and burned to
+
formation of carbon dioxide are necessary consequences of every
raise steam and generate electricity as in a thermal power station.
+
combustion process. One may think that this may deplete the world’s
Such an ‘energy plantation’ would be a renewable resource and
+
supply of oxygen and thus upset the oxygen-carbon dioxide balance
economical means of harnessing solar energy. However, the average
+
that is necessary for plant and animal life.
efficiency of solar energy conversion in these plants is about 1
 
percent and the overall efficiency of conversion of sunlight into
 
electricity would be about 0.3 percent as compared to 10 percent for
 
solar cells.
 
  
 
   
 
   
== Wind Energy ==
+
Carbon dioxide molecules strongly absorb heat
+
radiations emitted from the surface of the earth heated by the sun.
Wind is produced by
+
By holding back this energy in the earth’s atmosphere, carbon
temperature differences in the air. This is true both of a gentle
+
dioxide reduces the heat lost by the earth to space. This is called
evening breeze as well as a roaring hurricane. The main driving
+
‘greenhouse effect’ and because of this, it is argued, the
force behind the wind system of the earth’s atmosphere is the
+
continued burning of fossil fuels will result in a steady increase in
temperature difference between the tropics and the Polar Regions.  
+
the earth’s surface temperature. However, an increasing in the
This temperature difference arises due to the fact that the tropical
+
temperature of the earth’s surface and lower atmosphere has the
regions of the earth are much warmer than the Polar Regions. Wind
+
compensating effect of increasing evaporation and cloudiness.
energy is the energy of air in motion and has been used for ages for
+
Because clouds reflect some of the incident sunlight, increases in
driving sail boats, for grinding grain and pumping water.
+
cloudiness tend to decrease the surface temperature. Further, the
 +
release of particulate matter into the atmosphere from fuel burning
 +
increases the number of condensation sites around which water
 +
droplets can form. The result is an increase in the amount of rain,
 +
hail and thunderstorms which lead to the lowering of the temperature.
 +
The amount of carbon dioxide is regulated by the presence of the
 +
ocean waters which 60 times as much carbon dioxide as does the
 +
atmosphere and absorbs a large fraction of the carbon dioxide
 +
released by the burning of fuels. Also, the increased level of
 +
carbon dioxide in the atmosphere actually stimulates a more rapid
 +
growth of plants. This increased utilization of carbon dioxide
 +
further reduces the atmospheric excess. Thus the role of carbon
 +
dioxide in influencing the world’s climate is quite a complex one.
  
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_59310382.jpg]]Today
+
Carbon monoxide is another pollutant produced by
it is also used for generating electric power. When air is blown on
+
burning of fossil fuel. It is usually produced when there is
wind vane, a child’s common toy, starts rotating. This idea is
+
insufficient oxygen for burning. It is released into the atmosphere
used in making the windmill which is nothing but a big wind vane.
+
mainly from automobile exhaust gases. But it does not so far
Wind energy is inexhaustible and is therefore a permanent source of
+
constitute a serious environmental problem.
energy as there will always be winds. According to an estimate,
+
 
about 175 to 220 thousand trillion watt hours per year of wind energy
 
can be produced globally, This is a very promising figure as it is
 
about 2.7 times the total energy used on the earth today.
 
 
 
 
   
 
   
== Hydroelectric Power ==
+
=== Thermal pollution ===
 
   
 
   
Running water is an
+
The term ‘thermal pollution' basically refers to
easily available source of energy. It is available free and does not
+
the detrimental effects of discharges of unwanted heat into the
pollute the environment. Running water can be used to burn a turbine
+
environment. All electricity generating plants produce electricity
generator to produce electricity and is the basis of the
+
by driving huge turbine generators with steam. The steam is
hydroelectric plant. Water is stored in a reservoir behind a dam.
+
condensed in a cooling system and is cycled back to the heating unit
When water flows from a height, it turns big turbines to generate
+
for reuse. The cooling system can be water that is pumped from some
electricity. There are a number of hydroelectric power plants in
+
nearby reservoir and discharged back into it, or it can be a cooling
India; the Bhakra Nangal dam in punkab, Damodar valley Project in
+
tower in which the heat is dissipated into the atmosphere. Both
West Bengal, Hirakud Project and Kosi Project in Bihar and the
+
cause thermal pollution. If the heated water is discharged into a
Nagarjunasagar project in Andhra Pradesh to name a few. These
+
static reservoir, such as a lake, the effect can be even more
projects produce a very significant percentage of the total
+
severe. The thermal is generated by the energy producer as well as
electricity generated in our country.
+
the energy user. Almost all of the energy we use is eventually
 +
converted into heat. Most of this waste is dissipated into the air
 +
where it contributes to the general atmospheric heating.
  
 
   
 
   
=== Ocean energy ===
+
=== Effects of Nuclear Radiations ===
 
   
 
   
Tides are the raising
+
Nuclear reactors, unlike the other sources of
and filling of the ocean level due to the moon’s gravitational pull
+
power, offer a lot of advantage. Nuclear reactors generate
which can be easily seen along the seashore. It is possible to
+
electrical power without the smoke and fumes that are characteristic
extract energy from these tides and the main requirement for
+
of fossil fuel-burning plants. Also the mining of uranium produces
harnessing tidal energy is that the difference between the high tide
+
much less degradation of the countryside than the mining of fossil
and the low tide should be large, at least a few metres. The first
+
fuels, particularly coal. Nuclear reactors, therefore, offer the
ever tidal powered electric generating plant was set up on River
+
prospect of long term relatively clean power. However, nuclear
Rance in France, to harness the power tides in the English Channel
+
reactors have their own peculiar set of disadvantages, mainly
which rise to as much as 14 metres at this location. By opening
+
associated with the production of radioactive materials. Some
gates as the tide rises and then closing them at high tide, a
+
radioactive waste is released into the environment both gases into
23-square kilometers pool is formed behind the Rance river dam. As
+
the atmosphere and in the form of low activity waste such as tritium
the tide falls, the trapped water is allowed to flow out, driving 24
+
in cooling water.
electricity generating turbines of 13MW capacity each for total
 
average power output of 310MW.
 
  
 
   
 
   
It is estimated that
+
All radioactive substances emit harmful
the total global potential for tidal power is only2 percent of the
+
radiations, some of which can cause cancer in man and animals and
world’s potential hydroelectric capacity. Besides, it involves
+
damage the genetic material of the cell, producing long term harmful
very high initial cost and the output is variable.
+
effects in living organisms. However, modern nuclear reactors are
 +
quite safe. An individual living near a nuclear reactor is exposed
 +
much less to its emitted radiation than what one gets from X-rays and
 +
natural sources.
 +
 
 +
 +
= Energy and the future =
 +
 +
The worldwide demand for energy is increasing day
 +
by day. The increasing use of modern means of transport-cars, buses,
 +
trains, aero planes , ships, etc., the rapid rise in the overall
 +
industrialization; the tremendous growth in population, particularly
 +
in the last 40 years, are some of the factors that have led to a
 +
tremendous spurt in mankind’s energy requirements.
  
 
   
 
   
=== Energy from waves ===
+
=== Need for  Judicious Use of energy ===
 
   
 
   
Unlike the tides which
+
It follows therefore that mankind has to adopt a
exhibit a regular but long periodic variability, waves keep the ocean
+
judicious approach towards consumption of energy sources to ensure
water in continual motion. The vertical rise and fall of the
+
that these are not depleted too fast. This approach needs to be
successive waves can be used to produce energy. India’s first wave
+
supplemented by optimum utilization of our natural sources. We have,
energy project has gone on stream at vizhinjam near Trivandrum. The
+
for example, reserves of billions of tones of coal spread across the
150-MW project implemented by the Wave Energy Group attached to the
+
Bihar, West Bengal and Orissa region. This coal may not be of the
Ocean Engineering Centre, IIT, Madras, in association with the state
+
best quality, but coal mining in this area can always be stepped up
Harbour Engineering department. This project works works on the
+
to meet our energy requirements. In India, technology used is coal
principle of an oscillating water column, which drives an air
+
mining and handling after it is mined is still primitive where
turbine. The turbine is so designed that it rotates in one
+
mechanical wheels are used in open pit mining. Any improvement in
direction, irrespective of the direction of air flow. It is a
+
material handling system can lead to a saving of a lot of coal which
multipurpose scheme and floats on the sea bed. From the ecological
+
is otherwise lost'''.'''
and environment points of view too, it is the best as the unit hardly
 
leaves any waste. The biggest advantage of the project is that power
 
generation is possible throughout the year, though not uniformly.
 
 
 
       
 
{| border="1"
 
|-
 
|
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m550953e9.jpg]]
 
  
 
   
 
   
|
+
One source of energy which has remained
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m44b8741.jpg]]
+
underutilized is the hydroelectric energy. The subcontinent has many
 
+
large rivers with substantial hydroelectric potential, much of which
+
still remains unutilized. These can be tapped to provide energy
|}
+
which is clean, renewable and cheap. Large numbers of small
=== Energy from Ocean Thermal Gradients ===
+
hydroelectric power projects across the country over the country over
+
small rivers could also yields a fair amount of energy.
The heat contained in
 
the ocean waters heated by the sun can be converted into electricity
 
by utilizing the difference in temperature between the surface water
 
can be used to heat some low-boiling organic liquid such as ammonia
 
or propane, the vapours of which are allowed to expand through a
 
turbine which can run a generator. The vapours leaving a turbine are
 
channeled into a condenser located in the low temperature water zone,
 
much below the water surface. The condensed liquid is pumped into a
 
boiler evaporator to start the cycle afresh. The expected efficiency
 
of such a system is about 2 percent. The amount of energy available
 
from ocean thermal gradients is enormous, and is replenished
 
continuously.
 
  
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m533a134.jpg]][[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_196bef2b.jpg]]
+
Wind energy has a tremendous scope as alternative
 +
source of energy not only in India but the entire region stretching
 +
from Afghanistan to Vietnam. Wind electric generators are at present
 +
operating successfully in many parts of India. Windmills are also
 +
being used for pumping water and this use of windmills should be
 +
encouraged. If India develops a system whereby windmills and
 +
generators could be manufactured on a large scale, it will really be
 +
a tremendous boon to the rural economy of this vast region. Wind
 +
energy is a non-polluting, cheap, renewable source of energy.
  
== Geo thermal energy ==
 
 
   
 
   
We are
+
A substantial portion of our energy requirements
living between two great sources of energy- the sun up in the sky,
+
is met by firewood. It necessitates felling of trees, resulting in
and hot rocks beneath the earth’s surface. The interior of the
+
deforestation, soil erosion, and floods. To prevent this and to
earth is extremely hot. As one goes deep into the earth the
+
maintain the stability of forest reserves a massive afforestation
temperature increases. The earth has very hot materials in and below
+
programme is necessary. The use of firewood as fuel must be avoided
the crust. As some places this hot material comes quite close to the
+
as far as possible by encouraging the use of biogas plants. Benefits
surface, or even out of the surface in the form
+
accruing from biogas plants are immense and manifold. Biogas plant
of volcanic eruptions. In places where it comes close to the
+
generate but only substantial economic gains to the country but also
surface, underground water often gets heated and
+
help up gradation of the environment. As India is dependent on
produces steam and hot water which comes out as hot springs and
+
imported oil for meeting its energy requirements, it would be prudent
geysers. The areas in which such conditions exist are known as
+
to reduce the consumption of petroleum products. These are primarily
geothermal regions. Infrared photography of the ground from
+
used for road and rail transport. The industry uses a large quantity
satellites like IRS-1 has played an important role in locating the
+
of petroleum products both as raw material and also as fuel. There is
geothermal regions.
+
tremendous scope for reducing the consumption of diesel and petrol in
 +
cars, trucks and two wheelers by more efficient engine design and
 +
maintenance.
  
 
   
 
   
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m224b8bc5.jpg]]After
+
It is indeed a good news that India has vast
locating a geothermal region, a bore is drilled through the rock to
+
reserves of natural gas which is a very clean source of energy. The
tap the heat. In many places steam under high pressure comes out
+
Bombay High oilfields contain very large quantities of gas which at
straight from the borehole and can be used to drive turbines
+
present are flared or burnt. Only recently are efforts being made to
directly. Where steam is not available, cold water is pumped down
+
utilize natural gas commercially, for generating power and production
through one hole and heated water and steam produced pumped out of
+
of fertilizer. Especially in the north east. The Dutch and the
another. The hot water or steam produced can be used to run a turbine
+
British have found vast reserves of offshore natural gas and in the
or to heat housed and offices. Geo thermal energy is used for space
+
process have developed new technology to utilize it.
heating where the temperature goes down to 30 to 35 degrees below the
 
freezing point, for poultry farming, mushroom cultivation and
 
pashmina-wool processing which need a warmer climate.
 
  
 
   
 
   
Although at first
+
=== Minimizing Wastage ===
glance, geothermal energy seems very promising, geothermal sources
 
are, in reality, far from being pollution free. Underground steam
 
contains hydrogen sulphide gas and minerals which can poison fish and
 
other forms of aquatic life in streams and rivers.
 
 
 
 
   
 
   
== Key vocabulary ==
+
Not only have we to adopt a judicious approach to
+
using our energy sources, we have also to lay a great stress on
# Radiation-In general the emission of energy from a source, either as waves or as moving particles.
+
prevention of wastage. Even a casual look at our day-today
# Quartz-The most abundant mineral, consisting of crystalline silicon dioxide and having diverse physical properties and uses.
+
activities reveals that energy is wasted in many ways. Careless
# Semiconductor-A material, such as Silicon or germanium, that has a resistivity midway between that of conductors and that of insulators.
+
habits, like leaving the lights and fans on when no one is round,
+
keeping the car or scooter engine on while gossiping with a friend on
== Additional web resources ==
+
the road, etc. contribute to wastage of energy. We have to know
+
about the various ways in which energy is wasted at home and in
1)
+
industries, and then develop-and encourage others to develop-proper
[[http://news.discovery.com/tech/five-ways-harness-solar.html]]
+
design and also ensure that all machinery is kept well maintained and
 
+
in proper running condition. This helps save a lot of energy. With
+
the impending energy crisis facing mankind, saving ‘every bit of
2)
+
energy ‘ is of great importance. This saved energy can then be put
[[http://www.youtube.com/watch?v=0OkqJw1oTMk]]
+
to some useful ‘use’ in future. WE must remember energy saved is
 +
energy produced.
  
 
   
 
   
# [[http://www.youtube.com/watch?v=tSBACzRE3Gw&feature=related]] 4)[[www.indiacore.com/.../kssidhu-non-]][[conventional]][[-]][[energy]][[-]][[resources]][[.pdf]]
+
= Evaluation: =
# [[http://www.darvill.clara.net/altenerg/geothermal.htm]]
 
 
   
 
   
6)
+
# What is work?When do we say that work is done?
[[http://solarwaterheater.20m.com/RenewableEnergyVideo.html]]
+
# What are kinetic and potential energy?
 
+
# What are the different forms of energy?
 +
# What is power?
 +
# What are the units of energy?
 +
# What are fossil fuels?How are they formed?
 +
# What are the different steps to process the petroleum?
 +
# What is Biomass energy? How it is generated?
 +
# What are the different sources of non -conventional energy?
 +
# What are the different ways of harnessing solar energy?
 +
# Name the different non conventional sources of energy.
 +
# Name the different storage devices.
 +
# What are isotopes? Name some isotopes.
 +
# Draw the diagrams of the nuclear reactors-thermal and fast breed
 +
# How are fossil fuels threatening us?
 +
# What are the effects of Carbon Dioxide and Carbon Monoxide?
 +
# How are nuclear radiations affect out environment?
 +
# What is the need for judicious use of available energy?
 +
# List some steps to minimize energy wastage
 
   
 
   
7)[[www.physics.wisc.edu/~himpsel/wires.html]]
+
= Additional web resources =
 
 
 
   
 
   
= Energy storage =
+
# [[http://www.youtube.com/watch?v=8J_z3_3pue0]]
+
# [[Image:Energy%20for%20KOER_html_m145a4ee8.gif]][[Image:Energy%20for%20KOER_html_mb374f76.gif]][[http://www.youtube.com/watch?v=sOa7EpJf89I&feature=related]]
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m7a21910d.jpg]]One
+
# [[http://www.youtube.com/watch?v=S0TurHQp_AE&feature=related]]
of the problems associated with the generation of electricity from
+
# web.mit.edu/8.02t/www/materials/modules/ReviewD.pdf – This review document summarizes the law of conservation of energy very clearly
various is that the demand for power fluctuates. During the day, the
+
# [[http://www.youtube.com/watch?v=f9kJwtayTJ]]
power requirements, especially for commercial purposes, are much
+
# [[http://www.youtube.com/watch?v=VJfIbBDR3e8]]
greater than during night time. If there was some way to store
+
# [[http://www.youtube.com/watch?v=f9kJwtayTJI]]
electrical energy, the generating plant could be operated at full
+
# [[www.sciencejoywagon.com/physicszone/05work-energy/]]
capacity during the night, storing up energy to be released when the
+
# [[www.technologystudent.com/energy1/less4.html]]
demand increases.
+
# [[http://video.nationalgeographic.com/video/player/environment/energy-environment/alternative-energy.html]]
 
+
# [[http://news.discovery.com/tech/five-ways-harness-solar.html]]
+
# [[http://www.youtube.com/watch?v=0OkqJw1oTMk]]
There are two different approaches for storing
+
# [[http://www.youtube.com/watch?v=tSBACzRE3Gw&feature=related]]
electricity energy, depending upon whether this storage is for
+
# [[www.indiacore.com/.../kssidhu-non-conventional-energy-resources.pdf]]
small-scale or large-scale purposes.
+
# [[http://www.darvill.clara.net/altenerg/geothermal.html]]
 
+
# [[http://solarwaterheater.20m.com/RenewableEnergyVideo.html]]
+
# uw.physics.wisc.edu/~himpsel/wires.html
== Small-scale storage ==
+
# hyperphysics.phy-astr.gsu.edu/hbase/nucene/'''fission'''.html
+
# phet.colorado.edu/en/simulation/'''nuclear'''-'''fission'''
For small-scale storage of electricity, batteries
+
# www.whatis'''nuclear'''.com/articles/nuc'''reactor'''.html
and fuel cells offer the best course. An electric battery consists
+
# [[http://www.youtube.com/watch?v=SePyzzRiE5U]]
of one or more electric cells which are devices for producing
+
# [[http://www.youtube.com/watch?v=e-0Jf-zuG4s]]
electric directly from the chemical reactions. Electricity made in
+
# [[http://www.youtube.com/watch?v=zDGcD8Ix9Ek]]
this way is much more expensive than that made by mechanical
+
# [[www.whatisnuclear.com/articles/nucreactor.html]]
generators but batteries being compact and portable, are a better
+
# [[www.westinghouse]][[nuclear.com/.../WhatIsNuclearEnergy.shtm]]
choice for many applications Cells are generally of two types;
+
# [[www.indianuclearenergy.net]]
primary cells and secondary cells.
+
# '''video.nationalgeographic.com/video/.../energy.../alternative-energy.html '''
 
+
# ''en.wikipedia.org/wiki/'''''''Waste'''''''_minimisation'' - [[Cached]] – [[Similar]]
+
# www.youtube.com/watch?v=FBTXQV7GKow
One good example of a primary cell is a voltaic
+
# ''www.streetdirectory.com/.../''''energy''''-''''crisis-in-india''''-aouac.html'' - [[Cached]] – [[Similar]]
cell which consists of copper and zinc metal plated dipped in a
 
solution of sulphuric acid which acts as an electrolyte. The
 
electrolyte contains positive and negative ions but is overall
 
electrically neutral. Zinc tends to dissolve in the solution more
 
easily than does copper. In solution it forms positive zinc ions
 
leaving electrons behind on the zinc plate. This gives zinc plate a
 
negative charge with respect to copper plate and so, when an electric
 
circuit is completed at the terminals of the cell, the electrons flow
 
to the copper plate giving rise to a current. This cell becomes dead
 
when the solution becomes saturated with zinc so that no more of it
 
wants to dissolve. To revive the cell one has just to replace the
 
electrolyte sulphuric acid, this can be continued so long as zinc is
 
present but when the zinc is gone, the cell is permanently dead. The
 
principal disadvantage of the primary cell is its short life.  
 
Obviously it would be more useful to have a cell which could be
 
restored to its original condition once it had discharged all its
 
available form of energy. Fortunately it is possible to do so with
 
some types of cells. Such cells are called secondary cells and a set
 
of them is called a storage battery because it enables charges
 
produced by other means to be stored for later use. In a storage
 
battery electricity is stored where chemical changes take place which
 
can be reversed to release the stored electrical energy. A typical
 
storage battery takes a few hours to charge and can then be used as a
 
source of energy.
 
 
 
 
These batteries find use in the fabrication of
 
uninterrupted power supplies for continuous operation of costly
 
equipment, computers and other strategic gadgets. Here the batteries
 
are coupled with an oscillator which converts this D.C supply from
 
this battery to A. C. at higher voltage and frequency.
 
 
 
 
== Large scale storage ==
 
 
For meeting the large energy requirements of homes
 
and industry, storage batteries are impractical. '''Key
 
vocabulary'''
 
 
 
 
# Electrolyte-A liquid containing positive and negative ions, that conducts electricity by the flow of those charges
 
 
= Nuclear power =
 
 
== Atoms ==
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m4cc0b6df.jpg]]All
 
matter is made up of different naturally occurring elements, each
 
possessing physical and chemical properties distinct from the other.  
 
These smallest entities into which these elements can be divided are
 
called atoms. Atoms are made up of three still smaller
 
particles-positively charged protons, negatively charged electrons
 
and electrically neutral neutrons. The relatively heavy protons and
 
neutrons constitute the tiny nucleus. This is surrounded by moving
 
electrons and overall the orbit is electrically neutral and is about
 
ten to the power of 5 times the size if the nucleus. The number of
 
orbiting electrons is always equal to the number of protons so that
 
the net electrical charge of the atom is Zero.
 
 
 
 
Atoms of a particular element always contain the
 
same number of protons and there is a scale of elements, going from
 
the atoms of hydrogen which have only one proton, helium atoms which
 
have two protons, lithium atoms which have three protons, and so on
 
all way up to very large atoms such as uranium, which has 92 protons.
 
The number of protons is therefore, important because it identifies
 
the element to which the atom belongs. Thus any atom which contains,
 
say 17 protons must be chlorine; uranium atoms always contain 92
 
protons, and so on. The atomic number of an element is the same as
 
the number of protons in the nucleus.
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m2a27ed59.gif]]
 
Along with the protons in the atomic nucleus there are also the
 
electrically neutral particles called neutrons. The number of
 
neutrons in the nucleus tends to increase with number of protons.  
 
For instance, in the helium atom ( which has two protons) there are
 
two neutrons, lithium (which has three protons) has four neutrons,
 
uranium (which has 92 protons) has 146 neutrons, and so on. The
 
protons and neutrons in a nucleus are bound together by immensely
 
strong forces, called nuclear forces which counteract the
 
electrostatic forces of repulsion acting between the protons. In
 
very large atoms, such as uranium and plutonium, the binding nuclear
 
forces are only slightly stronger than the repulsive forces between
 
the large number of protons; such nuclei are unstable and can be made
 
to undergo fission- split into two or more fragments releasing
 
nuclear energy.
 
 
 
 
== Isotopes ==
 
 
The atomic weight of an element is expressed as
 
the sum of the number of protons and neutrons. Atoms of the same
 
element can differ from one another by having a different number of
 
neutrons in their nuclei. For example, uranium (which has 92
 
protons) can have either 143 or 146 neutrons. These two forms of
 
uranium have the same chemical but slightly different physical
 
properties. Atoms of the same element which exist in different forms
 
as a result of having different numbers of neutrons in their nuclei
 
are called isotopes. The first of the two uranium isotopes described
 
above is called uranium-235, and the second, uranium-238.
 
Uranium-238 is heavier than uranium-235. Similarly there are three
 
isotopes of hydrogen, namely hydrogen (one proton only), deuterium or
 
heavy hydrogen ( one proton and one neutron), and tritium ( one
 
proton and two neutrons).
 
 
 
 
Atoms of the same element always contain the same
 
number of protons in their nuclei. The number of protons is balanced
 
by an equal number of electrons to make the atom electrically
 
neutral. It is the number of orbiting electrons that determines the
 
chemical properties of an element. When atoms combine with other to
 
form molecules, there is rearrangement of the outermost electrons in
 
the orbit ( also called valence electrons). In this process, energy
 
can be stored or released so that is some reactions ( burning for
 
example) heat energy is released. Thus atoms of carbon ( coal, on
 
combination with atoms of oxygen from the air to form carbon dioxide
 
in the process of burning, release energy.
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m798592ab.gif]]Chemical
 
reactions, such as burning, involve the release of energy mainly due
 
to exchange or transfer of electrons whereas nuclear energy involves
 
the release of energy from within the nucleus of the atoms.
 
 
 
 
== Principle of Nuclear Fission ==
 
 
Isotopes of certain very heavy atoms, for example,
 
uranium-235 and plutonium-239, are so unstable that they can be made
 
to split (fission) when hit by a neutron. When this happens, a very
 
large amount of energy is released. This process is known as nuclear
 
fission. In this process, the mass of the two smaller atoms (
 
collectively known as fission products) plus the mass of the two or
 
three neutrons that are produced, is slightly less than the mass of
 
the original uranium-235 or plutonium-239 atom plus the bombarding
 
neutron. Thus, in the process of nuclear fission, some matter is
 
lost and converted into energy. According to Einstein’s famous
 
equation, even a small amount of matter is equivalent to a very large
 
amount of energy. Thus the nuclear fission of uranium-235 contained
 
in 1 tonne of natural uranium is equivalent in electricity output to
 
the burning of approximately 20,000 tonnes of coal. Natural uranium
 
contains only 0.7 percent of uranium-235.
 
 
 
 
== Nuclear Reactors ==
 
 
A nuclear reactor is a device in which the nuclear
 
fission process is carried out under controlled conditions. The
 
basic fuel of a nuclear reactor is uranium, obtained from ores such
 
as pitchblende. Natural uranium is a mixture of two isotopes,
 
uranium-235 and uranium 238, present in the ratio of 0.7:99. Only
 
the comparatively rare isotope uranium-235 undergoes nuclear fission.
 
 
 
 
There are two types of nuclear reactors:
 
 
 
 
# '''Thermal reactors''' use uranium as fuel and have moderators to slow down neutrons. They are called thermal reactors because they use slow-moving or thermal neutrons.
 
# '''Fast breed reactors: '''Since 99.3 percent of natural uranium is uranium-238 and since this isotope cannot undergo fission, thermal reactors are able to use a very small proportion of natural uranium. However, fast reactors are able to convert this otherwise unusable uranium-238 into a new element, plutonium-239, which can then be fissioned to liberate energy. Fast breeder reactors do not need a moderator as fast neutrons used.
 
 
'''Thermal reactors: '''The core of
 
a thermal has five components.
 
Uranium dioxide pellets are packed in long metal tubes known as fuel
 
elements. A nuclear reactor contains several tones of uranium in
 
thousands of fuel elements. Periodically, the used-up fuel elements
 
are taken out and new fuel elements put in. The most commonly used
 
moderators used moderators are water, heavy water, and graphite.
 
 
 
 
Control rods are used to control the rate of the
 
nuclear chain reaction. They are made of boron which readily absorbs
 
neutrons. When these rods are lowered into the core (containing fuel
 
elements and the moderator), that absorb most of the neutrons and so
 
there can be no chain reaction. This effectively shuts down the
 
reactor. As they are pulled out progressively, neutrons are
 
available to split uranium atoms, thus releasing more neutrons. The
 
further the control rods are pulled out, the larger is the number of
 
fissions in the core and more heat is produced.
 
 
 
 
Since the uranium fuel as well as the fission
 
products are intensely radioactive, a very thick steel-and-concrete
 
shield is required to prevent the escape of any radiation from the
 
core. Indian reactors usually have double shielding to further
 
minimize any risk.
 
 
 
 
To remove the heat produced by nuclear fission in
 
the fuel elements, a coolant is used which circulates through spaces
 
between the fuel elements, Indian reactors, which use natural
 
uranium as fuel, use heavy water as coolant, but reactors using
 
enriched uranium (in which the percentage of uranium-235 is raised by
 
complex processes) use ordinary water as coolant. The heated coolant
 
coming out of the core transfers the heat exchanger to boil water and
 
raise steam which is then used to run a turbine generator to generate
 
electricity.
 
 
 
 
== Fast breed reactors ==
 
 
Thermal reactors are able to release energy from
 
the small proportion of uranium-235 contained in the natural uranium.
 
They are, however, unable to use the uranium-238 which constitutes
 
99.3 percent of natural uranium. The significance of fast reactors
 
is that they are able to convert Uranium-238 into plutonium-239 in
 
significant quantities, so that much into plutonium-239 in
 
significant quantities, so that much more energy can be extracted
 
from natural uranium than is possible with thermal reactors.
 
 
 
 
There are two important features of fast breeder
 
reactors. Firstly, there is no moderator. The neutrons given off in
 
the fission reaction are not slowed down. ( It is for this reason
 
that this type of reactor is known as a fast reactor.
 
 
 
 
Secondly, the fuel elements of fast reactors
 
contain a mixture of plutonium-239 and uranium-238. Plutonium is
 
placed in the centre of the core, whereas the uranium-238 is located
 
in a blanket surrounding the plutonium core. Two processes take
 
place simultaneously in these reactors:
 
 
 
 
(i)Plutonium-239 (originally produced from some of
 
the uranium-238 atoms) in thermal reactors is fissioned, producing
 
heat which is removed by the coolant. Since the heat produced in the
 
core is very large, the coolant used in a fast reactor is liquid
 
sodium.
 
 
 
 
(ii)A significant proportion of uranium-238 is
 
converted into plutonium in the blanket. In fact more plutonium is
 
bred in the blanket than is fissioned in the core, and for this
 
reason, fast reactors are known as fast breeder reactors.
 
Plutonium-239 atoms are created when uranium-238 atoms absorb fast
 
moving neutrons.
 
 
 
 
=== Spent fuel ===
 
 
In both thermal and fast reactors, the spent fuel
 
elements contain three types of material: (i)highly radioactive
 
fission products; (ii)large amounts of unused uranium-238, known as
 
‘depleted’ uranium; and (iii) a certain among of plutonium. By
 
reprocessing the fission products from spent fuel, the plutonium and
 
depleted uranium can be fabricated into new fuel elements for fast
 
reactors. By repeated processes through fast reactors followed by
 
reprocessing, it is possible to extract much more energy than when
 
using only thermal reactors. 1 tonne of natural uranium fissioned in
 
a thermal reactor is equivalent to about 20,000 tonnes of coal. Used
 
in fast reactors, however, 1 tonne of natural uranium is equivalent
 
to about 1,000,000 tonnes of coal.
 
 
 
 
== Nuclear Fusion ==
 
 
What is happening inside the sun?
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_m413290ce.jpg]]The
 
sun consists mainly of hydrogen gas. The atoms of hydrogen under
 
tremendous pressure at the centre of the sun, come together and fuse
 
to for helium nucleus along with the liberation of tremendous energy
 
in the form of heat and light. It this energy which maintains its
 
temperature and makes the sun shine. In this process again, like in
 
nuclear fission, mass is converted into energy. This is also the
 
principle on which the hydrogen bomb is based. Since the various
 
reactions taking place inside the sun occur at very high
 
temperatures, they are called thermonuclear reactions. The sun,
 
therefore, may be considered as a thermonuclear furnace where
 
hydrogen atoms are continuously being fused into helium atoms. Mass
 
lost during these fusion reactions Is converted into energy.
 
 
 
 
The process of nuclear fission involves the
 
splitting of a heavy nucleus while the nuclear fusion is the joining
 
together of lighter atoms to form heavier ones. Both the processes,
 
however, release tremendous amounts of energy.
 
 
 
 
There are several possible reactions in which
 
light atoms can fuse r form heavier nuclei and release energy, but
 
the one which the scientists which have been trying to accomplish is
 
the thermonuclear reaction involving deuterium and tritium nuclei and
 
not hydrogen nuclei. This is due to the fact that though ordinary
 
hydrogen is the raw material for the thermonuclear process in the
 
sun, its reaction rate is quite slow. Reactions involving deuterium
 
nuclei or deuterium and tritium nuclei are more efficient. Fusion of
 
two nuclei of deuterium of deuterium forms a tritium and a hydrogen
 
nuclei while the fusion of a deuterium and a tritium nuclei forms a
 
helium nucleus with two protons and two neutrons.
 
 
 
 
For the above reactions to take place, the
 
colliding deuterium nuclei should have enormous speed. This is made
 
possible by heating the particles to a few hundred million degrees.
 
Remember, much below this temperature, the atoms are already stripped
 
of their electrons. Thus they form a mixture of positively charged
 
ions and electrons known as plasma.
 
 
 
 
If one can fuse all the nuclei in 1 gram of
 
deuterium, it would yield 100,000 kWh of energy. A complete fission
 
of an equivalent amount of uranium, on the other hand will give
 
25,000kWh.
 
 
 
 
=== Fusion Reactors ===
 
 
Despite its tremendous potential there are many
 
technical problems in building a practical fusion reactor. One major
 
problem is the confinement and control of plasma at more than a
 
hundred million degrees so that thermonuclear energy could be made
 
available at a steady rate. One very successful method to confine
 
the plasma in a magnetic field.
 
 
 
 
Among other alternatives being tried for
 
harnessing nuclear fusion is one by using lasers. A laser is a
 
highly powerful beam of coherent beam of coherent light which can be
 
focused on a very small spot. In this method, called inertial
 
fusion, pellets of deuterium-tritium fuel are rapidly compressed and
 
heated by bombardment with laser beams, resulting in a series of
 
miniature thermonuclear explosions and production of energy.
 
 
 
 
One of the most serious problems in the nuclear
 
fusion process is the fact that large amounts of tritium is only
 
weakly radioactive, its chemical behavior is exactly the same as
 
ordinary hydrogen and it can readily enter into organic substances.
 
Control of tritium will be one of the major problems in the operation
 
of the fusion reactors.
 
 
 
 
There are many advantages of fusion power. The
 
fuel supply is plentiful and relatively inexpensive.
 
 
 
 
The world’s oceans constitute an inexhaustible
 
source of the primary fuel deuterium in the form of water; about one
 
molecule out of every 3,000 water molecules contains an atom of
 
deuterium. The products of fusion reactions are either stable
 
isotopes or they are only weakly radioactive. Radioactivity will
 
also be produced by the neutrons released in the reactions when they
 
are captured in the materials of the reactor.
 
 
 
 
Further, fusion reactors do not produce air
 
pollutants that contribute to acid rain or global warming. Despite
 
these advantages, however, immense difficulties are yet to be
 
overcome before energy generation can become feasible on a large
 
scale.
 
 
 
 
== Additional web resources ==
 
 
''1)
 
hyperphysics.phy-astr.gsu.edu/hbase/nucene/'''''''fission'''''''.html''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
''2)
 
phet.colorado.edu/en/simulation/'''''''nuclear'''''''-'''''''fission'''''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
''3)
 
www.whatis'''''''nuclear'''''''.com/articles/nuc'''''''reactor'''''''.html''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
''4)
 
''[[http://www.youtube.com/watch?v=SePyzzRiE5U]]
 
 
 
 
''5)
 
''[[http://www.youtube.com/watch?v=e-0Jf-zuG4s]]
 
 
 
 
''6)
 
''[[http://www.youtube.com/watch?v=zDGcD8Ix9Ek]]
 
 
 
 
''7)
 
www.whatis'''''''nuclear'''''''.com/articles/nuc'''''''reactor'''''''.html''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
''8)
 
www.westinghouse'''''''nuclear'''''''.com/.../WhatIs'''''''NuclearEnergy'''''''.shtm''
 
- [[Cached]]
 
– [[Similar]]
 
 
 
 
''9)
 
www.india'''''''nuclearenergy'''''''.net/''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
= Energy and the environment =
 
 
Modern society cannot exist without the production
 
and utilization of energy. Every month we have to pay direct charges
 
for use of electricity. Oil and gas in our homes and for the petrol
 
used in our cars. And there are also indirect charges that we pay
 
for the energy used in manufacturing processes and for the
 
transportation of the goods that we buy. In addition to these
 
charges, w pay also in terms of the effects that energy production
 
and energy utilization have on our world in terms of environment
 
pollution. Environmental pollution may be defined as the unfavorable
 
alteration of our surroundings. It may not be possible to estimate
 
monetary losses or many of the side effects associated with energy
 
production and energy utilization. What is the value of the health
 
impairment, for example, caused by the cars exhaust fumes? What value
 
do we place on the destruction of farmland and pollution of water
 
caused by strip mining for coal? What value is associated with the
 
loss of seaside beaches because of oil pills washing ashore? As a
 
matter of fact, as long as we continue to produce and utilize energy,
 
we will have to pay for these undesirable side effects. How much are
 
we willing to pay?
 
 
 
 
== Threats from Fossil fuels ==
 
 
Most of the energy that is generated throughout
 
the world at present is derived from the burning of fossil
 
fuels-coal, natural gas and petroleum products. There are numerous
 
environment problems associated with the extraction, transportation
 
and utilization of fossil fuels.
 
 
 
 
The most plentiful fuel source in the world is
 
coal. The highest quality coal(anthracite generally occurs
 
sufficiently far underground to require high-cost deep-mining
 
techniques. Further, anthracite generally contains a very high
 
percentage of sulphur and it cannot be used as a fuel without
 
expensive treatment to remove sulphur. Consequently in recent years,
 
there has been increased interest in the mining of lower quality but
 
relatively sulphur-free coal that lies close to the surface.
 
Strip-mining techniques are used for the extraction of this coal.
 
Strip mining for coal causes serious and continuing environmental
 
problems. One of the most serious problems associated with the
 
strip-mining of coal is the huge amount of land that is torn up in
 
the process. Unless rehabilitation measures are taken, the area
 
adjoining the strip mined land can suffer from landslides, erosion
 
and sedimentation.
 
 
 
 
Unlike coal, the extraction of oil does not
 
desecrate the land the way the strip-mining does. However, the most
 
serious environmental problem associated with oil-well drilling
 
occurs at offshore sites. Because of the many technical difficulties
 
inherent in offshore drilling, if a rupture occurs or if the drilling
 
opens a crack in the rock that contains the oil deposit, a major
 
leakage of oil into the water can occur before the damage is repaired
 
or the crack is sealed. The release of large amounts of oil into the
 
water can be injurious to the marine life. When the oil spreads over
 
water, the diffusion of oxygen into water is inhibited. This affects
 
the respiration of fish and other marine life. Oil pollution of sea
 
causes either problems too. Oil is pushed to the shore by the water
 
currents and winds, thereby spoiling the beaches.
 
 
 
 
== Combustion of fuel ==
 
 
The burning of fossil fuels releases a variety of
 
noxious gases and particulate matter into the atmosphere. The major
 
contributors to this atmospheric pollution are coal and oil and
 
natural gas by far is the least offensive of the fossil fuels , One
 
of the major problems with coal and oil is the presence of sulphur.
 
Depending upon the source, the sulphur content can be up to several
 
percent and upon combustion several oxides (particularly sulphur
 
dioxide) are produced. When sulphur dioxide is released into the
 
atmosphere, it combines with water vapour and forms sulphuric acid.
 
It is this sulphuric acid which is injurious to plant and animal
 
life. It has been found that atmospheric sulphuric acid eating the
 
limestone facings of many monuments and public buildings in urban
 
life. Sulphur dioxide is believed to cause cough, shortness of
 
breath and spasm of the larynx. It can cause acute irritation to the
 
membranes of the eyes resulting in excessive flow tears and redness.
 
When absorbed by plants beyond a certain level the plants cells
 
become inactive and are killed, resulting in tissue collapse and
 
drying of leaves. Sulphur dioxide is also known to interfere with
 
the respiratory and photosynthesis in plants.
 
 
 
 
The burning of petrol in internal combustion
 
engines is the major source of carbon monoxide, nitrogen dioxides and
 
hydrocarbons in the atmosphere. In addition, there are large
 
quantities of lead which are released into the atmosphere from high
 
octane petrol used in cars. All these pollutants and the products of
 
the photochemical reactions they undergo in presence of sunlight
 
contribute to the noxious known as smog. There seems at present no
 
escape from the health hazards of smog until some effective way is
 
found to remove the pollutants from the vehicular exhaust gases.
 
 
 
 
'''Effects of carbon Dioxide and carbon Monoxide:
 
'''
 
 
 
 
The consumption of oxygen and the
 
formation of carbon dioxide are necessary consequences of every
 
combustion process. One may think that this may deplete the world’s
 
supply of oxygen and thus upset the oxygen-carbon dioxide balance
 
that is necessary for plant and animal life.
 
 
 
 
Carbon dioxide molecules strongly absorb heat
 
radiations emitted from the surface of the earth heated by the sun.
 
By holding back this energy in the earth’s atmosphere, carbon
 
dioxide reduces the heat lost by the earth to space. This is called
 
‘greenhouse effect’ and because of this, it is argued, the
 
continued burning of fossil fuels will result in a steady increase in
 
the earth’s surface temperature. However, an increasing in the
 
temperature of the earth’s surface and lower atmosphere has the
 
compensating effect of increasing evaporation and cloudiness.
 
Because clouds reflect some of the incident sunlight, increases in
 
cloudiness tend to decrease the surface temperature. Further, the
 
release of particulate matter into the atmosphere from fuel burning
 
increases the number of condensation sites around which water
 
droplets can form. The result is an increase in the amount of rain,
 
hail and thunderstorms which lead to the lowering of the temperature.
 
The amount of carbon dioxide is regulated by the presence of the
 
ocean waters which 60 times as much carbon dioxide as does the
 
atmosphere and absorbs a large fraction of the carbon dioxide
 
released by the burning of fuels. Also, the increased level of
 
carbon dioxide in the atmosphere actually stimulates a more rapid
 
growth of plants. This increased utilization of carbon dioxide
 
further reduces the atmospheric excess. Thus the role of carbon
 
dioxide in influencing the world’s climate is quite a complex one.
 
 
 
 
Carbon monoxide is another pollutant produced by
 
burning of fossil fuel. It is usually produced when there is
 
insufficient oxygen for burning. It is released into the atmosphere
 
mainly from automobile exhaust gases. But it does not so far
 
constitute a serious environmental problem.
 
 
 
 
== Thermal pollution ==
 
 
The term ‘thermal pollution' basically refers to
 
the detrimental effects of discharges of unwanted heat into the
 
environment. All electricity generating plants produce electricity
 
by driving huge turbine generators with steam. The steam is
 
condensed in a cooling system and is cycled back to the heating unit
 
for reuse. The cooling system can be water that is pumped from some
 
nearby reservoir and discharged back into it, or it can be a cooling
 
tower in which the heat is dissipated into the atmosphere. Both
 
cause thermal pollution. If the heated water is discharged into a
 
static reservoir, such as a lake, the effect can be even more
 
severe. The thermal is generated by the energy producer as well as
 
the energy user. Almost all of the energy we use is eventually
 
converted into heat. Most of this waste is dissipated into the air
 
where it contributes to the general atmospheric heating.
 
 
 
 
== Effects of Nuclear Radiations ==
 
 
Nuclear reactors, unlike the other sources of
 
power, offer a lot of advantage. Nuclear reactors generate
 
electrical power without the smoke and fumes that are characteristic
 
of fossil fuel-burning plants. Also the mining of uranium produces
 
much less degradation of the countryside than the mining of fossil
 
fuels, particularly coal. Nuclear reactors, therefore, offer the
 
prospect of long term relatively clean power. However, nuclear
 
reactors have their own peculiar set of disadvantages, mainly
 
associated with the production of radioactive materials. Some
 
radioactive waste is released into the environment both gases into
 
the atmosphere and in the form of low activity waste such as tritium
 
in cooling water.
 
 
 
 
All radioactive substances emit harmful
 
radiations, some of which can cause cancer in man and animals and
 
damage the genetic material of the cell, producing long term harmful
 
effects in living organisms. However, modern nuclear reactors are
 
quite safe. An individual living near a nuclear reactor is exposed
 
much less to its emitted radiation than what one gets from X-rays and
 
natural sources.
 
 
 
 
= Energy and the future =
 
 
The worldwide demand for energy is increasing day
 
by day. The increasing use of modern means of transport-cars, buses,
 
trains, aero planes , ships, etc., the rapid rise in the overall
 
industrialization; the tremendous growth in population, particularly
 
in the last 40 years, are some of the factors that have led to a
 
tremendous spurt in mankind’s energy requirements. Since all this
 
energy has to come from the energy sources available on this planet,
 
scientists have calculated that the world’s present known stocks of
 
fossil fuels may not last for more than a 100 years or so.
 
 
 
 
== Need for  Judicious Use of energy ==
 
 
It follows therefore that mankind has to adopt a
 
judicious approach towards consumption of energy sources to ensure
 
that these are not depleted too fast. This approach needs to be
 
supplemented by optimum utilization of our natural sources. We have,
 
for example, reserves of billions of tones of coal spread across the
 
Bihar, West Bengal and Orissa region. This coal may not be of the
 
best quality, but coal mining in this area can always be stepped up
 
to meet our energy requirements. In India, technology used is coal
 
mining and handling after it is mined is still primitive where
 
mechanical wheels are used in open pit mining. Any improvement in
 
material handling system can lead to a saving of a lot of coal which
 
is otherwise lost'''.'''
 
 
 
 
One source of energy which has remained
 
underutilized is the hydroelectric energy. The subcontinent has many
 
large rivers with substantial hydroelectric potential, much of which
 
still remains unutilized. These can be tapped to provide energy
 
which is clean, renewable and cheap. Large numbers of small
 
hydroelectric power projects across the country over the country over
 
small rivers could also yields a fair amount of energy.
 
 
 
 
Wind energy has a tremendous scope as alternative
 
source of energy not only in India but the entire region stretching
 
from Afghanistan to Vietnam. Wind electric generators are at present
 
operating successfully in many parts of India. Windmills are also
 
being used for pumping water and this use of windmills should be
 
encouraged. If India develops a system whereby windmills and
 
generators could be manufactured on a large scale, it will really be
 
a tremendous boon to the rural economy of this vast region. Wind
 
energy is a non-polluting, cheap, renewable source of energy.
 
 
 
 
A substantial portion of our energy requirements
 
is met by firewood. It necessitates felling of trees, resulting in
 
deforestation, soil erosion, and floods. To prevent this and to
 
maintain the stability of forest reserves a massive afforestation
 
programme is necessary. The use of firewood as fuel must be avoided
 
as far as possible by encouraging the use of biogas plants. Benefits
 
accruing from biogas plants are immense and manifold. Biogas plant
 
generate but only substantial economic gains to the country but also
 
help up gradation of the environment. As India is dependent on
 
imported oil for meeting its energy requirements, it would be prudent
 
to reduce the consumption of petroleum products. These are primarily
 
used for road and rail transport. The industry uses a large quantity
 
of petroleum products both as raw material and also as fuel. There is
 
tremendous scope for reducing the consumption of diesel and petrol in
 
cars, trucks and two wheelers by more efficient engine design and
 
maintenance.
 
 
 
 
It is indeed a good news that India has vast
 
reserves of natural gas which is a very clean source of energy. The
 
Bombay High oilfields contain very large quantities of gas which at
 
present are flared or burnt. Only recently are efforts being made to
 
utilize natural gas commercially, for generating power and production
 
of fertilizer. Especially in the north east. The Dutch and the
 
British have found vast reserves of offshore natural gas and in the
 
process have developed new technology to utilize it.
 
 
 
 
== Minimizing Wastage ==
 
 
Not only have we to adopt a judicious approach to
 
using our energy sources, we have also to lay a great stress on
 
prevention of wastage. Even a casual look at our day-today
 
activities reveals that energy is wasted in many ways. Careless
 
habits, like leaving the lights and fans on when no one is round,
 
keeping the car or scooter engine on while gossiping with a friend on
 
the road, etc. contribute to wastage of energy. We have to know
 
about the various ways in which energy is wasted at home and in
 
industries, and then develop-and encourage others to develop-proper
 
design and also ensure that all machinery is kept well maintained and
 
in proper running condition. This helps save a lot of energy. With
 
the impending energy crisis facing mankind, saving ‘every bit of
 
energy ‘ is of great importance. This saved energy can then be put
 
to some useful ‘use’ in future. WE must remember energy saved is
 
energy produced.
 
 
 
 
 
 
 
 
 
 
 
== Additional web resources ==
 
 
'''1)video.nationalgeographic.com/video/.../energy.../alternative-energy.html
 
'''
 
 
 
 
2)
 
''en.wikipedia.org/wiki/'''''''Waste'''''''_minimisation''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
3) www.youtube.com/watch?v=FBTXQV7GKow
 
 
 
 
''4)
 
www.streetdirectory.com/.../''''energy''''-''''crisis-in-india''''-aouac.html''
 
- [[Cached]]
 
- [[Similar]]
 
 
 
 
= Activities =
 
 
 
Winding
 
the main spring of the time piece, once wound keeps unwinding and
 
driving the clockwork mechanism for many hours. The energy stored in
 
the coiled spring is potential energy.
 
 
 
 
In
 
a catapult, the rubber band is stretched and make the pebble let go.
 
Energy is stored (potential) when the rubber is in stretched
 
condition. When it is released, it is this stored energy that is
 
converted into the kinetic energy which makes the pebble go far and
 
fast. potential energy.
 
 
 
 
 
= Evaluation =
 
 
# What is work?When do we say that work is done?
 
# What are kinetic and potential energy?
 
# What are the different forms of energy?
 
# What is power?
 
# What are the units of energy?
 
# What are fossil fuels?How are they formed?
 
# What are the different steps to process the petroleum?
 
# What is Biomass energy? How it is generated?
 
# What are the different sources of non -conventional energy?
 
# What are the different ways of harnessing solar energy?
 
# Name the different non conventional sources of energy.
 
# Name the different storage devices.
 
# What are isotopes? Name some isotopes.
 
# Draw the diagrams of the nuclear reactors-thermal and fast breed
 
# How are fossil fuels threatening us?
 
# What are the effects of Carbon Dioxide and Carbon Monoxide?
 
# How are nuclear radiations affect out environment?
 
# What is the need for judicious use of available energy?
 
# List some steps to minimize energy
 
 
= Additional Information =
 
 
Energy requirements for various
 
Activities
 
 
 
 
'''( in kilocalories/hour)'''
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_79ae7f48.gif]]
 
 
 
 
 
 
Light work
 
Moderate work
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_79ae7f48.gif]]Sitting
 
19 Shoe making 80-115
 
 
 
 
Writing
 
20 Sweeping 85-110
 
 
 
 
Standing relaxed 20 Dusting
 
110
 
 
 
 
Typing 16-40 Washing
 
125-215
 
 
 
 
Typing quickly 55 Charring
 
80-160
 
 
 
 
Sewing 30-90 Metal
 
working 120-140
 
 
 
 
Dressing and
 
Carpentering 150-180
 
 
 
 
Undressing
 
33 House painting 145-240
 
 
 
 
Drawing 40-50 Walking
 
130-
 
 
 
 
Violin playing 40-50
 
 
 
 
Tailoring 50-85
 
 
 
 
Ironing 60
 
 
 
 
Washing dishes 60
 
 
 
 
Book binding 45-90
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_36b949c8.gif]]
 
 
 
 
 
 
Hard work
 
Very Hard work
 
 
 
 
[[File:Energy_Resource_Material_Subject_Teacher_Forum_September_2011_html_3c3aa152.gif]]Polishing
 
175 Stone masonry 350
 
 
 
 
Joiner work 195 Sawing wood
 
420
 
 
 
 
Blacksmithing 275-350 Coal mining
 
320
 
 
 
 
Riveting 275 Running
 
800-1,000
 
 
 
 
Marching 280-400 Climbing 400-900
 
 
 
 
Cycling 180-600 Walking very
 
quickly 570
 
 
 
 
Rowing 120-600 Rowing very
 
quickly 1,240
 
 
 
 
Swimming 200-700 Running very
 
quickly 1,240
 
 
 
 
   
 
   
Skiing 500-9[[File:50
+
<br>
 +
<br>
  
 
   
 
   
Wrestling 1,000
+
[[Image:Energy%20for%20KOER_html_m798592ab.gif]]<u>Keywords
 +
– Work, Energy, Power, Kinetic Energy, Potential Energy, Law of
 +
Conservation of Energy, Thermodynamics, Biomass, Fossil Fuel,
 +
Combined Cycle Power Generation</u>

Revision as of 15:32, 25 September 2012

Introduction

This is a resource document for teachers on the various topics of energy covered in high school. This contains resource and reference material for the teachers as well as classroom-based activities and discussions that the teacher can use to build conceptual clarity and understanding.


This resource contains sections on what does energy mean, the relation between work done and energy, various forms of mechanical energy and the units of measuring power. Further conversion between various forms of energy is explored. The resource also discusses renewable and non-renewable energy sources with a detailed discussion on atominc energy as well. Energy flow in the universe and eecosystem is also discussed to connect the living ecosystem to the sources of energy, particularluy solar energy. Energy storage and management are also discussed in this resource. Where necessary, activities have been described in detail for the teacher to use in the classroom. The resource also points to additional web resources.


Energy is the basis of human life. Every single aspect of human experience whether it be in the external world or what we do or what is done to us can be adequately described either as a transfer of energy in one form from one place to another or the transformation of energy from one form to another. What is the meaning of energy? How does one measure it? What are the various forms in which energy manifests itself? How is energy obtained and transformed from one form to the other? How can energy be conserved? How do the production and utilization of energy in its various forms affect our environment? What is the source of all energy? What kind of energy flows and conversions take place in the environment? These are some questions we will explore here.


Concept Map




Energy for KOER html m5d4a74f5.jpg





Work, Energy and Power

We often use the terms work in ordinary conversation. Further, we also say that energy is needed to do work. We will explore the idea of work done, energy, power and energy conversions in this section.


Some of the key ideas to be covered in this section are:


  1. Work has a physical meaning in relation to the force operating and this is linked to the concept of energy. Such work done can be measured in physical terms.
  2. What do we mean when we say an object has energy? We are introduced to the idea of kinetic and potential energy.
  3. Effectivesness of doing work is called power; work, energy and power have units of measure.

Concept flow

What does work done mean?

We often use the terms work in ordinary conversation. We say for example “This job requires a lot of work”. What does ‘work’ really mean here? Further, we also say that energy is needed to do work. We will explore the idea of work done, energy, power and energy conversions in this section.


Work always involves some opposing forces. What do we mean by this? If we lift a box from the ground level and place it on a high shelf, we feel tired after the job is completed; we feel that we have done some work. How is this done? Gravity pulls the box and hence we are doing work against this gravitational force. This is true for any type of work.


Suppose that instead of lifting the box, we push it across a rough floor. In this case, we are not working against the gravitational force-the box is at the same height throughout the movement. Instead, we are now working against the frictional force that exists between the moving the box and the floor.


In physical terms, work done is directly proportional to both the applied force and the distance through which the force acts.


How do we measure work here?


We know that there is some cause, a force that results in a change in state of an object. When such a change in state occurs, it often results in a change in energy of the object. Is this waiter carrying a tray doing work?


When force acts over a period of time, there is an impulse I = F x t = m(v – mu) is the change in momentum of the body. Let us now look at what happens when force acts on an object over a distance along the direction of the force. In we say work is done by a force if the force acts on an object over a distance and we say that the work done W = Force F x distance travelled along the direction of the force.


Energy for KOER html m7d349003.pngNotice that the work done is the same in all the three cases above though the force applied is different. Greater the angle of inclination, greater is the force needed.


Thus W = F x d if the distance travelled d is in the same direction as the force. If the direction in which the object is moving is at angle θ then the distance travelled in the direction of the force would be d Cos θ and the work done would be W = f x d Cosθ.


Energy for KOER html 6f7bb14c.gifIf the force is acting perpendicular to the direction of the work done, there is no work done. If you are carrying a heavy bag in your hand and walking, though you may feel tired, no work is done in the physical sense, because there is no energy change that has occurred for the bag.


Work done, is defined as a particular form of product of two vectors – force and displacement. Such a product is called the scalar product and the resulting quantity is a scalar. In the context of work done, this is easy to understand. You don’t do work in a particular direction – you just do work.


The unit of work done is joules. 1 J of work is said to be done when a force of 1 N causes a displacement of 1 m.


When work is done, it is done over a certain time. The rate of doing work is defined as the power. Power is defined as (work done)/ time taken.


Power = work done/ time = force x displacement/ time = force x velocity


Its unit is Watt.


Energy, types of energy-Kinetic and potential

When an object is moved against a force, work is done and energy is spent in the process. Thus we say “A person must have a lot of energy to do a hard day’s work”. In fact one way to define energy is: Energy is the capacity to do work.


The word ‘energy’ is derived from the Greek energia'''-en means '''‘in’''' and ergon''', means '''work.


Energy for KOER html 77958556.jpgEnergy for KOER html 4c924b2.jpg

















Energy is defined for an object in a particular state. When work has been done on an object, its energy changes. At a very basic level, there are two forms of energy – kinetic energy and potential energy.


For example, a block is lying at rest on a table. It is pushed and it acquires a uniform velocity. Now the block has acquired some energy (kinetic energy, as we will define shortly). While the cause of the change in the state was a force (the push), it has resulted in the body acquiring a change in energy.


We can see that there are two ways of describing this (and for that matter, any) process. One is to study the cause (the force) and the other is to examine the change in energy.


Understanding Kinetic Energy


If an object is moved from rest to a uniform velocity, horizontally, it has acquired kinetic energy. Conversely, if an object is moving with a velocity ‘v’ and has to be stopped, work needs to be done. Let us understand this mathematically.


Let us say an object of mass ‘m’ is moving with a velocity ‘v’ and is brought to rest by a retarding force over a distance ‘s’


The acceleration = v2/ 2s


The force required = m x a


= m x v2/ 2s


Work done = force x displacement


= (m x v2/ 2s) x s


= ½ m v2


This is the expression of the kinetic energy that the object had.


If this object is a car and it was brought to rest by braking, the kinetic energy was lost as heat energy due to friction (braking) between the road and the car tires. The total energy remains conserved; it merely moves from one form to another.


All energy is due to motion and is kinetic energy. The energy that an object possesses by virtue of its motion is Kinetic energy.


Energy for KOER html m23570b7e.gifUnderstanding Potential Energy


If an object is lifted from the ground to a certain height, work has been done in moving it and this is stored in the object as potential energy. If the object is dropped, it will fall to the ground with a velocity and will acquire kinetic energy.


  • Potential energy can be more usefully understood and described as potential for energy. When a body has potential energy, it has the capacity to do work. When a spring is compressed, work has been done on it. If it is released, the spring can do work. The potential (for) energy that it has allows the spring to do work.
  • Energy for KOER html 7e8255f0.gifIt is also useful to think of potential energy in terms of change in energy level with respect to a zero. The surface of the earth has been arbitrarily assumed to be at zero potential energy.
  • The potential for energy is with respect to a zero defined for a system. The potential energy is, therefore, always to be referred to in terms of a system. The potential energy of the object-earth system was changed when it was lifted to a height ‘h’.

If an object of mass ‘m’ is raised to a height ‘h’, work has been done.


Work done = m x g xh


= mgh


This is stored in the object as potential energy and when the object falls, gets converted into kinetic energy. In this particular case, the potential energy is referred to as gravitational potential energy. An object can also possess potential energy if it is put under strain. Then it has energy stored in it because of the work done to bring it in that condition. In a time piece, the main spring, for example, once wound keeps unwinding and driving the clockwork mechanism for many hours. Here the coiled spring has energy stored in it because of the work done on it while winding.


Potential energy is the potential for energy that is built in an object. The energy that an object possesses when it is lifted to a height or it is put under strain is potential energy.


Activity 1 (Self-evaluation for student)

Energy for KOER html m13b54311.gifKnowing that the PE at the top of the stairs is 50 J, what is the potential energy at the various positions?




Potential Energy – Kinetic energy changes during free fall



Conservation of energy

The key idea here is that the total energy of the system is conserved. Potential energy can be converted into kinetic energy and vice versa. But the total energy remains unchanged.


In more general terms, the law of conservation of energy states that energy can neither be created nor destroyed; but can be transformed from one form to another.


Activity : Conservation of mechanical energy in a pendulum

Objectives:

  1. To study the motion of a simple pendulum
  2. To observe the different factors on which the motion of a simple pendulum depends
  3. Develop an understanding that gravity is a conservative force

Method:

Energy for KOER html m72c98b84.pngUse the PhET simulation Pendulum Lab.


For this we will need to open an application called PhET on the computer. You can find PhET under Applications> Education> Science. PhET is an educational resource that contains computer demonstrations of experiments and activities. When we click on Play with sims – it will open simulations in various subjects. We will click on Physics and scroll down to the simulation on Pendulum Lab.


When we want to open a simulation, we click on the green rectangle which says “Run Now”.


Running the simulation

Screenshot #1


Energy for KOER html m6465bb7e.pngQuestions:


  1. Notice where the pendulum is – is it higher, lower or at the same level as the central position?
  2. Notice the graph – what are the two variables on the bar chart?
  3. What do you think will happen to the pendulum next?

Screenshot #2


Energy for KOER html m4498abd8.pngQuestions:


  1. Notice where the pendulum is – has it moved? What can you say about its movement?
  2. Notice the graph – what are the variables on the bar chart?
  3. What are the values of PE and KE as compared to total energy?

Screenshot #3


Energy for KOER html 706b8b67.png Questions:


  1. Notice where the pendulum is – has it moved? Is it higher or lower than the central position?
  2. Did you notice anything about the speed of the bob as it moves from one extreme position to another?
  3. Notice the graph – what are the variables on the bar chart?
  4. What has happened to the values of the KE and PE as compared to total energy?
  5. What do you think is happening? Is this what you will think will happen when you try this experiment? Why? Why not? What is different?

Screenshot #4


Energy for KOER html 1fe1122b.png


Questions:


  1. Notice where the pendulum is. This extreme position to the right is at a different height than before. Why? What role does friction play and where does it come from
  2. Look at the graph – what are the variables in the bar chart? Where has the thermal energy come from?
  3. What do you expect will happen to the simple pendulum?

Mechanics of the simple pendulum

The motion of a pendulum is a classic example of mechanical energy conservation. A pendulum moves it sweeps out a circular arc, moving back and forth in a periodic fashion. Neglecting air resistance (which would indeed be small for an aerodynamically shaped bob), there are only two forces acting upon the pendulum bob. One force is gravity. The force of gravity acts in a downward direction and does work upon the pendulum bob. However, gravity is an internal force (or conservative force) and thus does not serve to change the total amount of mechanical energy of the bob. The other force acting upon the bob is the force of tension. Tension is an external force and if it did do work upon the pendulum bob it would indeed serve to change the total mechanical energy of the bob. However, the force of tension does not do work since it always acts in a direction perpendicular to the motion of the bob. At all points in the trajectory of the pendulum bob, the angle between the force of tension and its direction of motion is 90 degrees. Thus, the force of tension does not do work upon the bob.


Since there are no external forces doing work, the total mechanical energy of the pendulum bob is conserved.


Power, energy units and conversions

One important aspect of the processes producing or using or/and converting energy from one form to another is the rate at which this is done. For example, two persons perform equal amounts of work by lifting identical boxes from the ground level and keeping them on a shelf .One of them does this rapidly while the other does it slowly. Although the total work done by each person is the same, the two persons work at different power levels. The faster working person converts his body’s chemical energy into work at a more rapid rate than the slowly working person


Power is the rate at which work is done or energy is used or supplied and may therefore be calculated by dividing the work done (or energy used or supplied) in the process by the time taken by the process. Work is done over a certain time. Rate of doing work is power. Power is different even if energy is the same.


Energy or work is measured in Joules (J) and time is measured is seconds (s) and so the unit of power is the joule per second (J/s), This unit is given the special name WATT (W) where


1watt =1 J/s


1000watt =1 kilowatt=1kw


1000,000 watt =1megawatt=1MW


1,000,000,000watt =1gigawatt=1GW


1,000,000,000,000watt =1terawatt=TW


A commercial unit energy that we often hear about on out electricity bills is the kilowatt hours (kwh). 1kilowatt hour is the energy used or supplied when 1kw power is used or supplied for one hour. 1kwh is equal to 3.6 million joules.


Energy Units and conversions

The basic unit for the measurement of energy in the metric system is the joule, but there are also other units in common usage. The kilowatt hour is usually used to describe electrical energy. The calorie which is defined as the amount of heat energy required to raise the temperature of 1g of water through 1degree Celsius, is the unit primarily used to measure heat and also to describe the energy content of food stuff.


Energy in the world

The transformations of energy from one form to another and the efficiency of the transformation processes are studied in Physics, Chemistry and Biology. While so far we have discussed potential energy and kinetic energy (expressed as thermal energy in molecules), we see around us energy in various forms such as electrical energy, solar energy tidal energy hydro energy, geothermal energy and so on. All these forms of energy fall under the two categories of energy kinetic and potential. Potential energy is the stored energy and the energy of position and can be understood as potential for energy. Chemical energy, nuclear energy, stored mechanical energy and gravitational energy are all forms of potential energy.


In this section, we will explore the following:


  1. Matter contains internal energy caused due to molecular motion
  2. Energy can be conveted from one form into another

Energy in matter

The molecules in every bit of matter solid, liquid or gas are in a continual state of motion. This random motion of molecules(or atoms) constitute an internal kinetic energy or thermal energy that an object possesses even though the object as a whole may not be in motion. Thermal energy is thus manifestation of the motion of the molecules of a substance. A change in the thermal energy of an object can be brought about by supplying heat to the object. For example, by repeatedly hitting a block of metal with a hammer, its atoms are caused to move rapidly, thereby raising the thermal energy of the metal block which as a result becomes hot.


The primary source of all energy on the Earth is the Sun, though there are some small amounts of energy that come from the Earth's interior as well as cosmic radiation. Tidal energy is also caused by the gravitational pull of the Earth. Powered by the Sun, energy constantly flows through the Earth's surface and environment.


Laws governing the energy of the universe

Studying the flow of energy and understanding the processes in the world is called thermodynamics. This branch of science involved asking questions about how processes happen in the world around us. For example, why are certain processes irrevesible? What makes a chemical reaction takes place? When does heat flow from one object to another?


Exploration of these concepts resulted in the formulation of two laws:


  1. The first law of thermodynamics states that the total energy of a system and its surroundings remains constant. In other words, the energy of the universe is constant. This law implies that energy is conserved and the energy content of the system takes two forms - work and heat.
  2. The second law of thermodynamics states that the entropy of the universe is always increasing. This can be summarized by stating that the universe always moves in a direction of increasing randomness.

Some processes of energy conversion

We have seen that energy occurs in various forms. These different forms of energy can be converted from one form to another.


  • For example, when we switch on an electric light firstly, we can see the transfer of electrical energy from the power plant to our home, and then the conversion of electric energy into heat energy, part of it into visible light. This light energy is not destroyed but it is absorbed by the walls, ceiling and floor and other objects, finally to be converted into heat. Electric energy → heat energy+ light energy
  • In a power plant, chemical energy stored in fossil fuels such as coal, oil or gas is converted into heat energy in the boiler by combustion. This heat energy changes water from liquid state to steam. This heat energy of steam is converted in part, into mechanical energy in the steam turbine. This mechanical energy is then converted into electrical energy in the generator. From the generator it is transferred by the electric cables to various points where it can be used for further transfer to homes and industries etc., Chemical energy → heat energy → steam energy → mechanical energy electrical energy → light energy+ heat energy+ mechanical energy
  • In the running of a car the chemical energy hidden in the explosive mixture of petrol vapour and air is converts by the spark into heat energy. The heat energy, in turn is converted in part, into mechanical energy of motion of the pistons in the cylinders. The mechanical energy of the pistons is transferred to the drive shaft and from there to the wheels to move the car. Chemical energy → heat energy → mechanical energy
  • All biological processes throughout the domain of living things can also be shown to be energy conversion processes. The digestion of food is a combination of rather complicated processes but what it amounts to is the transformation of chemical energy locked in the food into heat energy to keep the body warm, and into mechanical energy to enable the body to do work by moving its various parts or itself as a whole besides synthesizing some compounds. There is also some conversion into electrical energy to establish communication between various parts of the body through the nervous system.
  • Chemical energy → heat energy + mechanical energy + electrical energy In all the above examples energy is converted from one to another, but the total energy in any energy conservation process always remains constant; that is energy can neither be created nor destroyed. This is the law of conservation of energy.

Biological energy flow

We saw earlier that energy flows constantly through the Earth and its environment. Plants fix the solar radiation into carbohydrates and form the basis of much of the energy flow in the world. Either through the food chain or through the accumulation as fossil fuels, this accounts for the bulk of the energy in the world.


Concept Flow

  1. Energy flows are essential to life processes and we need to study biological energy flows also to understand flow of energy.
  2. We cannot discuss energy without discussing the connection with food and how energy flows through living organisms through food. This flow of energy through living organisms is called a food chain.

Energy flow in an ecosystem

An ecosystem is a community where living and non-living things interact. There are two main processes in an ecosystem – energy flow and nutrient flow. The energy flow in an ecosystem happens through the food chain.


Activity: Energy flow through a food chain

Objectives

  1. To understand the way energy flows in an ecosystem
  2. To explore the connections between different cycles and processes in an ecosystem

Method

Watch the following videos on food chain


  • Food chain in Africa [[1]]
  • Interactions in an ecosystem [[2]]
  • Description of a food chain and web [[3]]
  • Interactions and energy flow in an ecosystem [[4]]

Questions:


  • When we say food web, what comes to your mind? Why do you think it is called food web?
  • What are the implications of laws of thermodynamics on how much energy is transferred in a food chain?
  • Can you think why there are few consumers and large number of producers? What happens when a consumer eats a producer?
  • In the local ecosystem, provide examples of each of these categories in your area – producer, consumer and decomposer?
  • For this web to work properly, what is needed?
  • What is energy flow? How does it flow – from small organisms to large or large organisms to small? Why do you think so? What elements do you observe in the ecosystem that give you this idea?
  • Is the tiger 'bad' because it ate the goats? Why is the tiger eating the goat?

Methods of energy flow

The laws of thermodynamics we saw earlier govern the processes in a food chain also. For example, the first law tells us that an organism can only use the energy it receieves whereas the second law tells us that not all of the energy received by an organism can be used – some of it will be lost as heat. At each level of the food chain, the amount of energy that gets transferred to the next trophic level is only a portion of the energy present in the lower level. This fraction varies widely across ecosystems. When finally organisms die and decay they pass the materials of life in simple forms to other organisms (nutrient flow). This energy flow is not cyclic – continuously less and less energy is available. So then, how do ecosystems continue? They depend on an external source of energy called the Sun. If the Sun's energy is not available in usable form, life on Earth may not be possible any longer.


Conventional sources of energy

We saw how the solar energy is responsible for producing organic compounds that sustain energy flow in the living world. Availability of energy resources and harnessing them for multiple applications have concerned the human society for centuties. Advances in technology and society have always been linked to the access of and use of natural energy resources. In this section, we will look at some of the major sources of energy that are used by human beings in our endeavours.


Concept flow

Some key ideas we will explore in this section are:


  1. Solar enerrgy is the source of almost all energy on the Earth
  2. Fossil fuels are exhaustible and needs thousands of years to form.
  3. Biomass energy which comprises parts of living things is also a source of energy.

Forest

Firewood has been the major source of energy during most of man’s history and it continued to remain the most important fuel until the middle of nineteenth century. Firewood is obtained from the forests and is primarily used for heating and cooking. The other fuel which has been traditionally used here is animal dung cakes. The animal dung mainly consists of undigested plant material which on drying, gives a product that readily burns. One of the disadvantages of both firewood and animal dung cakes as fuels is that they give a lot of smoke on burning.


With the industrial revolution in Europe, people learned to transform the energy from coal to mechanical energy in machines. This led to increased demand for energy. The discovery of coal, followed by oil and natural gas fulfilled these demands to a large extent and these fuels since then have been the primary sources of world’s energy.


Fossil fuels

All these fuels - coals, oil and natural gas- are derived from the slow decay of living organisms such as trees, algae and small marine animals for millions of years and are therefore known as fossil fuels. The fossil fuels are being consumed at an appreciable rate. Although their new deposits continue to be discovered, the world reserves of these fuels are limited. Further, these energy sources take millions of years to form and therefore fossil fuels are also known as non-renewable sources of energy. These fuels once exhausted cannot be replaced quickly when exhausted. Hence these are also called as exhaustible resources.


Formation of fossil fuels

Coal

Energy for KOER html m7a3827ce.jpgFossil fuels-coal, oil and natural gas-are the result of decomposition of living matter. Coal is obtained from dead plant matter which consists primarily of carbon, hydrogen and oxygen.


Energy for KOER html m6d44a4fd.jpgOn dry land, this matter rots away by bacterial action in presence of atmospheric oxygen to form carbon dioxide and water. But in swampy locations, the dead plant matter is covered with water and is, therefore, protected from the oxidising action of air. Instead, it is attacked by bacteria which do not require free oxygen in order to live. In the process oxygen and hydrogen of the dead plant matter gradually escape and the residue, therefore, becomes richer and richer in carbon. The end product of the bacterial action is a soggy, carbon-rich substance called peat.


Energy for KOER html m29549bc5.jpgOver long periods of time the peat is covered with sand, silt and clay. As peat gets compressed and heated further due to geological changes, more gases are forced out and therefore the proportion of carbon continues to increase. In this way, peat is gradually converted into various forms of coal such as lignite, bituminous coal and anthracite.


Petroleum and natural gas

In contrast to coal, the raw material in the formation of oil and natural gas consists mainly of marine organisms, mostly plants that grow near the surface of the sea. When these organisms die and accumulate in basins, where the water is stagnant, they are also protected from atmospheric oxidation. The dead marine matter is decomposed by anaerobic bacteria. Oxygen, nitrogen and other elements escape leaving mainly compounds of carbon and hydrogen called hydrocarbons. The accumulating covering layer of sediments provides heat and pressure that convert the hydrocarbon material into droplets of liquid oil and bubbles of natural gas. As more sedimentary deposits are laid down over periods of time, the pressure increases and the oil and gas are forced into nearby porous sand or sandstone. Gradually the oil and gas migrate upward through the sand and they then either escape to the surface or are trapped beneath layers of clay stone. This migration process separates the oil from underground water because water molecule readily adhere to sand whereas oil molecules do not. Thus the oil tends to collect in the pore spaces of sandy rocks beneath roof rocks with natural gases on the top.


Biomass Energy

Fossil fuels are derived from plants, trees and animals that lives millions of years ago. It took the remains of these organisms millions of years of burial under tremendous pressure and the internal heat to turn into coal, oil, or gas that we use as fuel today. We cannot get fossil fuels from the plant and animal waste that we produce today. But they, too form a substantial source of energy in the form of biomass. Biomass means the waste material and dead parts of animals that are living today. It includes garbage, industrial waste, crop residue, sewage and plant waste such as dead leaves and wood. These wastes can be both wet and dry. Wet wastes are in the form of animal excreta or domestic and industrial residues. Dry wastes refers to leaves, wood, paper, straw, fruit skin and others. There are two ways of using biomass as a source of energy. One is to burn the dry biomass directly to produce heat and generate steam. Another method is to convert this biomass into gaseous fuels called biogas by fermentation.


The raw material used for the production of biogas is cow dung mixed with water which is taken in an insulated, air-tight container called digester. In the digester, bacteria break the raw material into simpler chemicals by a process known as anaerobic decomposition. Other bacteria then convert the chemicals into a biogas for fuel. The gas consists of mainly methane and is drawn out through a gas outlet pipe.


Wet wastes from household and industries too can be used to produce methane gas. Wastes may be dumped in deep pits. Wells are then drilled down into the waste. A pipeline is then drilled down into the waste. A pipeline is then to recover the gas produced by the natural decomposition of the material.


From fossil fuel to electricity

The most convenient usable form of energy is electricity. In all the sources of energy above, the heat generated from the combustion of fuel is used to boil water to produce steam which powers a turbine. This mechanical energy of turbine is converted into electricity in generators. These stages involve various losses and therefore the overall efficiency of these plants is never more than 40 percent. It is, however, possible to cut short the above energy conversion stages and convert heat from the combustion of fuels directly into electricity using a magneto-hydro dynamic generator, popularly known as MHD generator, which works on the basic phenomenon of electromagnetic induction. Another method of increasing the efficiency of power generation is also through the use of combined cycle power plants.


Processing of coal and petroleum

Coal, which is essentially pure carbon, is chiefly used as a combustion fuel. The reaction of carbon with atmospheric oxygen to produce carbon dioxide is an exothermic reaction that releases about 7,840 kilocalories/kg of carbon and this reaction is responsible for the heat energy derived from burning coal. Burning of coal produces large quantities of fly ash and noxious gases such as a sulphur dioxide and related compounds which cause atmospheric pollution. Coal is therefore converted into a cleaner fuel, coke, by heating crushed coal to high temperatures in the absence of air. Coal can also be converted into liquid and gaseous fuels which can partially replace the fuels derived from petroleum.


Unlike coal and natural gas which can be used directly as fuels without processing, petroleum or crude oil is not directly usable. The name ‘petroleum’ is derived from the Latin words petra meaning ‘rock’ and oleum meaning ‘oil’. Therefore, it means rock oil, to distinguish it from animal or vegetable oils. Petroleum, also often called crude oil, is a mixture of hundreds of hydrocarbon compounds together with small amounts of compounds of other elements. The exact composition of crude depends upon many factors such as its age and the types of organisms from which it is formed. So, every deposit of crude oil is a unique mixture whose exact composition differs even from deposits separated from it vertically or horizontally by a few metres of rock. Natural gas is normally associated with crude oil. It is a mixture of gaseous hydrocarbons, mainly methane and ethane. The non-hydrocarbon compounds present in crude oil are mainly compounds of sulphur, nitrogen and oxygen. Other elements present in very small amounts include vanadium, nickel, chlorine, arsenic and lead.


Detection of Oil

The method generally used for locating oil deposits is the seismic survey. Shock waves generated by surface explosive charges travel through rock layers and are reflected back by various geological structures and possible locations where oil might be trapped can be found. To find whether oil is really present and whether it can be economically extracted, it is necessary to drill a well.


Extraction and refining of Oil

Once the oil has been found by drilling the well, the next step is to operate the well; that is, to raise the oil to the surface. After extraction, the oil is usually transported to a refinery through pipelines. From offshore platforms, the oil is sometimes transported to the shore in large tankers. The natural gas produced in the process is also transported by large pipelines.


Crude oil is processed in a refinery by fractional distillation. This process involves heating the crude oil in a tall tower so that various components are distilled out of it and can be trapped at various levels in the tower. In this process the use is made of the fact that the different hydrocarbon compounds in the crude have different boiling points and hence can be separated at its boiling point. The lightest compounds such as gases which have low boiling points rise to the top and the heavier oils with higher boiling points are collected lower down.


The various fractions may then be further processed by cracking or refining, both of which involve the use of catalysts-substances which facilitate the chemical reactions without themselves undergoing any change. Catalytic cracking, often called cat-cracking, is a means of breaking down the heavier distillates to form lighter compounds.


The various fractions obtained after refining are used for different purposes The gas fraction, like natural gas, is used chiefly as a fuel for heating. Petrol is used in spark ignition internal combustion engines that require a fairly volatile fuel. Kerosene is used as a lighting and cooking fuel in villages, and also in tractors and jet engines. Diesel is used in diesel engines.


Non conventional Sources of energy

The conventional sources of energy discussed in the previous section are exhaustible and cannot be quickly replaced when exhausted. It takes millions of years for these sources to be formed from the decay of living organisms. These sources are, therefore, also known as non-renewable sources of energy. In contrast, we have another class of the sources such as the sun, wind, waves, tides, and geothermal heat which are inexhaustible. These sources of energy are, therefore, known as renewable sources of energy.


Concept flow

  1. Unlike fossil fuels and to some extent, forest and biomass, non-conventional sources of energy are renewable and can potentially be used for longer periods of time
  2. A major problem in harnessing these sources of energy is that the energy released by them is highly diffused as compared with the energy obtained from fossil fuels or nuclear fuels.
  3. Considerable research is on to make these sources of energy viable.

Solar energy

The source of energy most readily available to us is the sun. Solar energy has several advantages over the other energy sources. It is inexhaustible; it is free from any pollution and unlike fossil fuels, transformation of solar energy does not produce any toxic by-products.


Nature provides some concentration of the sun’s energy in the form of wind and waves. The gradients set up in the atmosphere by solar heating turn some of its energy into the movement of large masses of air, thereby providing wind energy. This wind, in turn, whips up the waves in the sea which at places can provide highly concentrated energy. But none of these sources of energy in their natural form can as yet provide a viable alternative to the conventional sources. Therefore, global effort is on to tap energy in concentrated form from the non-conventional sources.


When solar radiation strikes the earth’s atmosphere, some of it is reflected by dust particles and clouds, some of it is absorbed by carbon dioxide, water vapour, ozone layer and the remaining reaches the earth’s surface. Most of the ultraviolet radiation is absorbed by the ozone layer. Some infrared radiation is absorbed by the ozone layer. Some infrared radiation is absorbed by clouds, carbon dioxide and water vapour. The amount of radiation, reaching the earth, thus may vary with the presence of clouds, humidity, the latitude- the position of the place north or south of equator, the time of year, the time of day and other factors. An idea of the magnitude of energy reaching the earth’s surface falling on an area equal to the size of the tennis court per day is roughly equal to the energy obtained from 135 litres of petrol or 180 kg of coal.


Harnessing Solar Energy

Solar energy can be harnessed in five ways:


  1. using solar panels
  2. solar thermal
  3. concentrated solar power
  4. solar nanowires and
  5. By using photosynthetic and biological processes.

However, before solar energy can be successfully utilized, two major problems need to be solved. Firstly solar energy is highly diffused; that is, it is thinly spread over the earth’s surface and so one needs to concentrate it, secondly, solar energy has to be stored for us during night or on a very cloudy day.


When sunlight concentrated by a convex lens is made to fall on a piece of paper, it burns. The problem of concentrating solar energy may be solved through the use of different types of reflectors for focusing sunlight. Reflectors are used in solar cookers and solar ovens. The simplest of these reflectors is a single reflector provided in hot-box type of solar cookers. It is a sheet of polished looking glass or aluminized plastic hinged to one side of the box which reflects solar radiation into the cooker and heats it. In a solar oven, several reflectors are provided on all sides of a box. Curved mirrors, parabolic reflectors and Fresnel lenses are also used in solar cookers.


Solar Thermal Power Generation

Generally two approaches are followed in this method of power generation


(1)sunlight reflected from several mirrors arranged in an array is focused on a single heat exchanger in a solar furnace; and


(2)a large number of cylindrical reflectors in a solar farm focus solar radiation on long pipes carrying a gas which collects the heat. A good example of the solar furnace approach is the tower concept. Sunlight is focused on to a boiler mounted on the top of a tower located near the centre of the field of mirrors to produce a high temperature for driving a steam turbine. Another similar plant system used arrays of heliostat-guided mirrors to focus sunlight into a cavity-type boiler near the ground to produce steam for a steam turbine electric power plant. Sunlight striking the mirrored faces of the heliostat modules is reflected and concentrated in the cavity of the heat exchanger.


In contrast to the solar furnace approach, in the solar farm, parabolic cylindrical concentrators or other types of concentrators are used to focus sunlight on to a central pipe surrounded by an evacuated quartz envelope. Heat collected by a fluid(nitrogen or helium) flowing through these pipes may be stored at a temperature over 500 degree Celsius in a molten salt. This heat may then be used to drive steam turbines for the generation of electricity


Photovoltaic Power Generation

Energy for KOER html m4d95859e.gifUnlike the solar thermal systems discussed above, solar cells offer a very attractive means for direct conversion of sunlight into electricity with high reliability and low maintenance. The disadvantages, however, are high cost and difficulty of storing large amounts of electricity as compared with the relative ease of storing heat for later use. The working of a solar cell depends upon the phenomenon of photo electricity; that is, the liberation of electrons by light falling on a body. Though this phenomenon has been known for a long time, its application to semiconductors such as silicon has proved to be of great use. The principle of solar cells is simple. When light waves strike a semi-conductor material with energy sufficient to dislodge an electron from a fixed position in the material and make it move freely in the material, a vacant electron position or ‘hole’ is created in the material. The hole acts a positive charge and can move if a neighbouring electron leaves its site to fill the hole site. A current is created if the electron-hole pairs are separated by voltage in the cell material. Such an intrinsic voltage may be created by adding small amounts of impurities or dopants to the pure material or by joining two semiconductor materials. When impurities such as phosphorous are introduced into silicon, it becomes electron-rich and is referred to as ‘n-type’ silicon. On the other hand, impurities such as boron give rise to ‘p-type’ silicon with excess of holes. When these two oppositely charged semiconductors (one electron rich and the other electron-deficient) are in contact, free charge leaks across the common boundary and becomes fixed as ions in the region adjacent to the boundary. At the interface, the fixed (but opposite) ions create an electric field that sends free electrons one way and free holes the other.


In the dark, no current flows in the solar cell. But when it is illuminated, a current will flow as long as the cell is illuminated and can supply electricity to an external load.


The best and most efficient solar cells are constructed from high purity silicon. This type of cell has already been used very successfully for providing electrical power in spacecraft. The overall efficiency of photovoltaic cells is around 11 percent. But their cost has prevented their use for large-scale generation


Conversion into Electrical Energy

The conversion of solar energy into electricity can be achieved via two routes:


(1) solar energy is used to boil water which can then be used to generate electricity (solar thermal power generation)


(2) direct conversion of solar energy into electricity using solar cells.


Wind Energy

Wind is produced by temperature differences in the air. This is true both of a gentle evening breeze as well as a roaring hurricane. The main driving force behind the wind system of the earth’s atmosphere is the temperature difference between the tropics and the polar regions. This temperature difference arises due to the fact that the tropical regions of the earth are much warmer than the polar regions. Wind energy is the energy of air in motion and has been used for ages for driving sail boats, for grinding grain and pumping water.


Today it is also used for generating electric power. When air is blown on wind vane, a child’s common toy, starts rotating. This idea is used in making the windmill which is nothing but a big wind vane. Wind energy is inexhaustible and is therefore a permanent source of energy as there will always be winds. According to an estimate, about 175 to 220 thousand trillion watt hours per year of wind energy can be produced globally, This is a very promising figure as it is about 2.7 times the total energy used on the earth today.


Hydroelectric Power

Running water is an easily available source of energy. It is available free and does not pollute the environment. Running water can be used to burn a turbine generator to produce electricity and is the basis of the hydroelectric plant. Water is stored in a reservoir behind a dam. When water flows from a height, it turns big turbines to generate electricity.


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Srisailam Dam across the Krishna River

The gravitational potential emergy of the water is converted into kinetic energy that powers the turbines to produce electricity. There are a number of hydroelectric power plants in India; the Bhakra Nangal dam in punkab, Damodar valley Project in West Bengal, Hirakud Project and Kosi Project in Bihar and the Nagarjunasagar project in Andhra Pradesh to name a few. These projects produce a very significant percentage of the total electricity generated in our country. However, large dams also have a high degree of environmental impact in terms of flooding and silting of the rivers. The environmental costs of the dams must be weighed against the benefits of the dams.


Ocean energy

Tides are the raising and filling of the ocean level due to the moon’s gravitational pull which can be easily seen along the seashore. It is possible to extract energy from these tides and the main requirement for harnessing tidal energy is that the difference between the high tide and the low tide should be large, at least a few metres. The first ever tidal powered electric generating plant was set up on River Rance in France, to harness the power tides in the English Channel which rise to as much as 14 metres at this location. By opening gates as the tide rises and then closing them at high tide, a 23-square kilometers pool is formed behind the Rance river dam. As the tide falls, the trapped water is allowed to flow out, driving 24 electricity generating turbines of 13MW capacity each for total average power output of 310MW.


It is estimated that the total global potential for tidal power is only2 percent of the world’s potential hydroelectric capacity. Besides, it involves very high initial cost and the output is variable.


Energy from waves

Unlike the tides which exhibit a regular but long periodic variability, waves keep the ocean water in continual motion. The vertical rise and fall of the successive waves can be used to produce energy. India’s first wave energy project has gone on stream at vizhinjam near Trivandrum. The 150-MW project implemented by the Wave Energy Group attached to the Ocean Engineering Centre, IIT, Madras, in association with the state Harbour Engineering department. This project works works on the principle of an oscillating water column, which drives an air turbine. The turbine is so designed that it rotates in one direction, irrespective of the direction of air flow. It is a multipurpose scheme and floats on the sea bed. From the ecological and environment points of view too, it is the best as the unit hardly leaves any waste. The biggest advantage of the project is that power generation is possible throughout the year, though not uniformly.


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Energy from Ocean Thermal Gradients

Energy for KOER html m533a134.jpgEnergy for KOER html 196bef2b.jpgThe heat contained in the ocean waters heated by the sun can be converted into electricity by utilizing the difference in temperature between the surface water can be used to heat some low-boiling organic liquid such as ammonia or propane, the vapours of which are allowed to expand through a turbine which can run a generator. The vapours leaving a turbine are channeled into a condenser located in the low temperature water zone, much below the water surface. The condensed liquid is pumped into a boiler evaporator to start the cycle afresh.


The expected efficiency of such a system is about 2 percent. The amount of energy available from ocean thermal gradients is enormous, and is replenished continuously.


Geo thermal energy

We are living between two great sources of energy- the sun up in the sky, and hot rocks beneath the earth’s surface. The interior of the earth is extremely hot. As one goes deep into the earth the temperature increases. The earth has very hot materials in and below the crust. As some places this hot material comes quite close to the surface, or even out of the surface in the form of volcanic eruptions. In places where it comes close to the surface, underground water often gets heated and produces steam and hot water which comes out as hot springs and geysers. The areas in which such conditions exist are known as geothermal regions. Infrared photography of the ground from satellites like IRS-1 has played an important role in locating the geothermal regions.


Energy for KOER html m224b8bc5.jpgAfter locating a geothermal region, a bore is drilled through the rock to tap the heat. In many places steam under high pressure comes out straight from the borehole and can be used to drive turbines directly. Where steam is not available, cold water is pumped down through one hole and heated water and steam produced pumped out of another. The hot water or steam produced can be used to run a turbine or to heat housed and offices. Geo thermal energy is used for space heating where the temperature goes down to 30 to 35 degrees below the freezing point, for poultry farming, mushroom cultivation and pashmina-wool processing which need a warmer climate.


Although at first glance, geothermal energy seems very promising, geothermal sources are, in reality, far from being pollution free. Underground steam contains hydrogen sulphide gas and minerals which can poison fish and other forms of aquatic life in streams and rivers.


Energy storage

We have seen that whatever the source of energy, all of these are converted into electrical energy for use. This brings to focus the need for energy storage and distribution.


One of the problems associated with the generation of electricity from various is that the demand for power fluctuates. During the day, the power requirements, especially for commercial purposes, are much greater than during night time. If there was some way to store electrical energy, the generating plant could be operated at full capacity during the night, storing up energy to be released when the demand increases.


Concept flow

Some of the key ideas in energy storage are:


  1. All forms of energy are used to generate electrical energy
  2. Generation, storage and transmission of electrical energy is involved in meeting energy demands
  3. There are two different approaches for storing electricity energy, depending upon whether this storage is for small-scale or large-scale purposes.

Small-scale storage

Energy for KOER html m7a21910d.jpgEnergy for KOER html bb112d6.pngFor small-scale storage of electricity, batteries and fuel cells offer the best course. An electric battery consists of one or more electric cells which are devices for producing electric directly from the chemical reactions. Electricity made in this way is much more expensive than that made by mechanical generators but batteries being compact and portable, are a better choice for many applications Cells are generally of two types; primary cells and secondary cells.


One good example of a primary cell is a voltaic cell which consists of copper


and zinc metal plated dipped in a solution of sulphuric acid which acts as an electrolyte. The electrolyte contains positive and negative ions but is overall electrically neutral. Zinc tends to dissolve in the solution more easily than does copper. In solution it forms positive zinc ions leaving electrons behind on the zinc plate. This gives zinc plate a negative charge with respect to copper plate and so, when an electric circuit is completed at the terminals of the cell, the electrons flow to the copper plate giving rise to a current. This cell becomes dead when the solution becomes saturated with zinc so that no more of it wants to dissolve. To revive the cell one has just to replace the electrolyte sulphuric acid, this can be continued so long as zinc is present but when the zinc is gone, the cell is permanently dead. The principal disadvantage of the primary cell is its short life. Obviously it would be more useful to have a cell which could be restored to its original condition once it had discharged all its available form of energy. Fortunately it is possible to do so with some types of cells. Such cells are called secondary cells and a set of them is called a storage battery because it enables charges produced by other means to be stored for later use. In a storage battery electricity is stored where chemical changes take place which can be reversed to release the stored electrical energy. A typical storage battery takes a few hours to charge and can then be used as a source of energy.


These batteries find use in the fabrication of uninterrupted power supplies for continuous operation of costly equipment, computers and other strategic gadgets. Here the batteries are coupled with an oscillator which converts this D.C supply from this battery to A. C. at higher voltage and frequency.


Large scale storage

For meeting the large energy requirements of homes and industry, storage batteries are impractical. To meet the requirements of varying demands, electricity generation is increased or decreased and in many cases, there is a transmission and distribution company that manages this kind of scheduling.


Nuclear energy

We have seen how different sources of energy are used to generate steam and hence the mechanical energy to produce electricity. These sources can be renewable or non-renewable. Yet another source that has been used to generate electrcity is nuclear energy, the atomic energy is used in the generation of energy. In this section, we will understand the atomic structure and the source of energy in the atom.


Concept flow

  1. Atoms consist of protons, neutrons and electrons. Different atoms and nuclei have different levels of stability. Atoms occur in more than one configuration due to difference in their nuclear structure and these different configurations are called isotopes.
  2. A vast amount of energy is available within the nucleu and nuclear reaction processes release this energy. Nuclear energy so produced is used in the place of coal or gas to heat water and produce steam. A nuclear reaction occurs when uranium atoms split intosmaller particles in a chain reaction that produces a large amount of heat.
  3. Chemical reactions, such as burning, involve the release of energy mainly due to exchange or transfer of electrons whereas nuclear energy involves the release of energy from within the nucleus of the atoms.

Atoms

All matter is made up of different naturally occurring elements, each possessing physical and chemical properties distinct from the other. These smallest entities into which these elements can be divided are called atoms. Atoms are made up of three still smaller particles-positively charged protons, negatively charged electrons and electrically neutral neutrons. The relatively heavy protons and neutrons constitute the tiny nucleus. This is surrounded by moving electrons and overall the orbit is electrically neutral and is about ten to the power of 5 times the size if the nucleus. The number of orbiting electrons is always equal to the number of protons so that the net electrical charge of the atom is Zero.


Atoms of a particular element always contain the same number of protons and there is a scale of elements, going from the atoms of hydrogen which have only one proton, helium atoms which have two protons, lithium atoms which have three protons, and so on all way up to very large atoms such as uranium, which has 92 protons. The number of protons is therefore, important because it identifies the element to which the atom belongs. Thus any atom which contains, say 17 protons must be chlorine; uranium atoms always contain 92 protons, and so on. The atomic number of an element is the same as the number of protons in the nucleus.


Energy for KOER html m2a27ed59.gifAlong with the protons in the atomic nucleus there are also the electrically neutral particles called neutrons. The number of neutrons in the nucleus tends to increase with number of protons. For instance, in the helium atom ( which has two protons) there are two neutrons, lithium (which has three protons) has four neutrons, uranium (which has 92 protons) has 146 neutrons, and so on. The protons and neutrons in a nucleus are bound together by immensely strong forces, called nuclear forces which counteract the electrostatic forces of repulsion acting between the protons. In very large atoms, such as uranium and plutonium, the binding nuclear forces are only slightly stronger than the repulsive forces between the large number of protons; such nuclei are unstable and can be made to undergo fission- split into two or more fragments releasing nuclear energy.


Isotopes

The atomic weight of an element is expressed as the sum of the number of protons and neutrons. Atoms of the same element can differ from one another by having a different number of neutrons in their nuclei. For example, uranium (which has 92 protons) can have either 143 or 146 neutrons. These two forms of uranium have the same chemical but slightly different physical properties. Atoms of the same element which exist in different forms as a result of having different numbers of neutrons in their nuclei are called isotopes. The first of the two uranium isotopes described above is called uranium-235, and the second, uranium-238. Uranium-238 is heavier than uranium-235. Similarly there are three isotopes of hydrogen, namely hydrogen (one proton only), deuterium or heavy hydrogen ( one proton and one neutron), and tritium ( one proton and two neutrons).


Atoms of the same element always contain the same number of protons in their nuclei. The number of protons is balanced by an equal number of electrons to make the atom electrically neutral. It is the number of orbiting electrons that determines the chemical properties of an element. When atoms combine with other to form molecules, there is rearrangement of the outermost electrons in the orbit ( also called valence electrons). In this process, energy can be stored or released so that is some reactions ( burning for example) heat energy is released. Thus atoms of carbon ( coal, on combination with atoms of oxygen from the air to form carbon dioxide in the process of burning, release energy.


Principle of Nuclear Fission

Energy for KOER html m4cc0b6df.jpgIsotopes of certain very heavy atoms, for example, uranium-235 and plutonium-239, are so unstable that they can be made to split (fission) when hit by a neutron. When this happens, a very large amount of energy is released. This process is known as nuclear fission. In this process, the mass of the two smaller atoms ( collectively known as fission products) plus the mass of the two or three neutronsa that are produced, is slightly less than the mass of the original uranium-235 or plutonium-239 atom plus the bombarding neutron. Thus, in the process of nuclear fission, some matter is lost and converted into energy. According to Einstein’s famous equation, even a small amount of matter is equivalent to a very large amount of energy. Thus the nuclear fission of uranium-235 contained in 1 tonne of natural uranium is equivalent in electricity output to the burning of approximately 20,000 tonnes of coal. Natural uranium contains only 0.7 percent of uranium-235.


Fission Nuclear Reactors

A nuclear reactor is a device in which the nuclear fission process is carried out under controlled conditions. The basic fuel of a nuclear reactor is uranium, obtained from ores such as pitchblende. Natural uranium is a mixture of two isotopes, uranium-235 and uranium 238, present in the ratio of 0.7:99. Only the comparatively rare isotope uranium-235 undergoes nuclear fission.


There are two types of nuclear reactors:


  1. Thermal reactors use uranium as fuel and have moderators to slow down neutrons. They are called thermal reactors because they use slow-moving or thermal neutrons.
  2. Fast breed reactors: Since 99.3 percent of natural uranium is uranium-238 and since this isotope cannot undergo fission, thermal reactors are able to use a very small proportion of natural uranium. However, fast reactors are able to convert this otherwise unusable uranium-238 into a new element, plutonium-239, which can then be fissioned to liberate energy. Fast breeder reactors do not need a moderator as fast neutrons used.

Thermal reactors

The core of a thermal has five components. Uranium dioxide pellets are packed in long metal tubes known as fuel elements. A nuclear reactor contains several tones of uranium in thousands of fuel elements. Periodically, the used-up fuel elements are taken out and new fuel elements put in. The most commonly used moderators used moderators are water, heavy water, and graphite.


Control rods are used to control the rate of the nuclear chain reaction. They are made of boron which readily absorbs neutrons. When these rods are lowered into the core (containing fuel elements and the moderator), that absorb most of the neutrons and so there can be no chain reaction. This effectively shuts down the reactor. As they are pulled out progressively, neutrons are available to split uranium atoms, thus releasing more neutrons. The further the control rods are pulled out, the larger is the number of fissions in the core and more heat is produced.


Since the uranium fuel as well as the fission products are intensely radioactive, a very thick steel-and-concrete shield is required to prevent the escape of any radiation from the core. Indian reactors usually have double shielding to further minimize any risk.


To remove the heat produced by nuclear fission in the fuel elements, a coolant is used which circulates through spaces between the fuel elements, Indian reactors, which use natural uranium as fuel, use heavy water as coolant, but reactors using enriched uranium (in which the percentage of uranium-235 is raised by complex processes) use ordinary water as coolant. The heated coolant coming out of the core transfers the heat exchanger to boil water and raise steam which is then used to run a turbine generator to generate electricity.


Fast breed reactors

Thermal reactors are able to release energy from the small proportion of uranium-235 contained in the natural uranium. They are, however, unable to use the uranium-238 which constitutes 99.3 percent of natural uranium. The significance of fast reactors is that they are able to convert Uranium-238 into plutonium-239 in significant quantities, so that much into plutonium-239 in significant quantities, so that much more energy can be extracted from natural uranium than is possible with thermal reactors.


There are two important features of fast breeder reactors. Firstly, there is no moderator. The neutrons given off in the fission reaction are not slowed down. ( It is for this reason that this type of reactor is known as a fast reactor.


Secondly, the fuel elements of fast reactors contain a mixture of plutonium-239 and uranium-238. Plutonium is placed in the centre of the core, whereas the uranium-238 is located in a blanket surrounding the plutonium core. Two processes take place simultaneously in these reactors:


(i)Plutonium-239 (originally produced from some of the uranium-238 atoms) in thermal reactors is fissioned, producing heat which is removed by the coolant. Since the heat produced in the core is very large, the coolant used in a fast reactor is liquid sodium.


(ii)A significant proportion of uranium-238 is converted into plutonium in the blanket. In fact more plutonium is bred in the blanket than is fissioned in the core, and for this reason, fast reactors are known as fast breeder reactors. Plutonium-239 atoms are created when uranium-238 atoms absorb fast moving neutrons.


Spent fuel

In both thermal and fast reactors, the spent fuel elements contain three types of material: (i)highly radioactive fission products; (ii)large amounts of unused uranium-238, known as ‘depleted’ uranium; and (iii) a certain among of plutonium. By reprocessing the fission products from spent fuel, the plutonium and depleted uranium can be fabricated into new fuel elements for fast reactors. By repeated processes through fast reactors followed by reprocessing, it is possible to extract much more energy than when using only thermal reactors. 1 tonne of natural uranium fissioned in a thermal reactor is equivalent to about 20,000 tonnes of coal. Used in fast reactors, however, 1 tonne of natural uranium is equivalent to about 1,000,000 tonnes of coal.


Nuclear Fusion

What is happening inside the sun?


Energy for KOER html m413290ce.jpgThe sun consists mainly of hydrogen gas. The atoms of hydrogen under tremendous pressure at the centre of the sun, come together and fuse to for helium nucleus along with the liberation of tremendous energy in the form of heat and light. It this energy which maintains its temperature and makes the sun shine. In this process again, like in nuclear fission, mass is converted into energy. This is also the principle on which the hydrogen bomb is based. Since the various reactions taking place inside the sun occur at very high temperatures, they are called thermonuclear reactions. The sun, therefore, may be considered as a thermonuclear furnace where hydrogen atoms are continuously being fused into helium atoms. Mass lost during these fusion reactions Is converted into energy.


There are several possible reactions in which light atoms can fuse to form heavier nuclei and release energy, but the one which the scientists which have been trying to accomplish is the thermonuclear reaction involving deuterium and tritium nuclei and not hydrogen nuclei. This is due to the fact that though ordinary hydrogen is the raw material for the thermonuclear process in the sun, its reaction rate is quite slow. Reactions involving deuterium nuclei or deuterium and tritium nuclei are more efficient. Fusion of two nuclei of deuterium of deuterium forms a tritium and a hydrogen nuclei while the fusion of a deuterium and a tritium nuclei forms a helium nucleus with two protons and two neutrons.


For the above reactions to take place, the colliding deuterium nuclei should have enormous speed. This is made possible by heating the particles to a few hundred million degrees. Remember, much below this temperature, the atoms are already stripped of their electrons. Thus they form a mixture of positively charged ions and electrons known as plasma.


If one can fuse all the nuclei in 1 gram of deuterium, it would yield 100,000 kWh of energy. A complete fission of an equivalent amount of uranium, on the other hand will give 25,000kWh.


Fusion Reactors

Despite its tremendous potential there are many technical problems in building a practical fusion reactor. One major problem is the confinement and control of plasma at more than a hundred million degrees so that thermonuclear energy could be made available at a steady rate. One very successful method to confine the plasma in a magnetic field.


Among other alternatives being tried for harnessing nuclear fusion is one by using lasers. A laser is a highly powerful beam of coherent beam of coherent light which can be focused on a very small spot. In this method, called inertial fusion, pellets of deuterium-tritium fuel are rapidly compressed and heated by bombardment with laser beams, resulting in a series of miniature thermonuclear explosions and production of energy.


One of the most serious problems in the nuclear fusion process is the fact that large amounts of tritium is only weakly radioactive, its chemical behavior is exactly the same as ordinary hydrogen and it can readily enter into organic substances. Control of tritium will be one of the major problems in the operation of the fusion reactors.


There are many advantages of fusion power. The fuel supply is plentiful and relatively inexpensive.


The world’s oceans constitute an inexhaustible source of the primary fuel deuterium in the form of water; about one molecule out of every 3,000 water molecules contains an atom of deuterium. The products of fusion reactions are either stable isotopes or they are only weakly radioactive. Radioactivity will also be produced by the neutrons released in the reactions when they are captured in the materials of the reactor.


Further, fusion reactors do not produce air pollutants that contribute to acid rain or global warming. Despite these advantages, however, immense difficulties are yet to be overcome before energy generation can become feasible on a large scale.


The process of nuclear fission involves the splitting of a heavy nucleus while the nuclear fusion is the joining together of lighter atoms to form heavier ones. Both the processes, however, release tremendous amounts of energy.


Energy and the environment

Modern society cannot exist without the production and utilization of energy. Every month we have to pay direct charges for use of electricity. Oil and gas in our homes and for the petrol used in our cars. And there are also indirect charges that we pay for the energy used in manufacturing processes and for the transportation of the goods that we buy. In addition to these charges, we pay also in terms of the effects that energy production and energy utilization have on our world in terms of environment pollution. Environmental pollution may be defined as the unfavorable alteration of our surroundings. It may not be possible to estimate monetary losses or many of the side effects associated with energy production and energy utilization. What is the value of the health impairment, for example, caused by the cars exhaust fumes? What value do we place on the destruction of farmland and pollution of water caused by strip mining for coal? What value is associated with the loss of seaside beaches because of oil pills washing ashore? As a matter of fact, as long as we continue to produce and utilize energy, we will have to pay for these undesirable side effects. How much are we willing to pay?


Concept flow

  1. Uncontrolled energy consumption places a strain on the environment
  2. Mining for coal and drilling for petroleum leads to destruction of land, pollution and habitat loss
  3. What are the ecological costs of oil spills, health lost and other such effects?
  4. There needs to be a judicious use of energy

Threats from Fossil fuels

Most of the energy that is generated throughout the world at present is derived from the burning of fossil fuels-coal, natural gas and petroleum products. There are numerous environment problems associated with the extraction, transportation and utilization of fossil fuels.


The most plentiful fuel source in the world is coal. The highest quality coal(anthracite generally occurs sufficiently far underground to require high-cost deep-mining techniques. Further, anthracite generally contains a very high percentage of sulphur and it cannot be used as a fuel without expensive treatment to remove sulphur. Consequently in recent years, there has been increased interest in the mining of lower quality but relatively sulphur-free coal that lies close to the surface. Strip-mining techniques are used for the extraction of this coal. Strip mining for coal causes serious and continuing environmental problems. One of the most serious problems associated with the strip-mining of coal is the huge amount of land that is torn up in the process. Unless rehabilitation measures are taken, the area adjoining the strip mined land can suffer from landslides, erosion and sedimentation.


Unlike coal, the extraction of oil does not desecrate the land the way the strip-mining does. However, the most serious environmental problem associated with oil-well drilling occurs at offshore sites. Because of the many technical difficulties inherent in offshore drilling, if a rupture occurs or if the drilling opens a crack in the rock that contains the oil deposit, a major leakage of oil into the water can occur before the damage is repaired or the crack is sealed. The release of large amounts of oil into the water can be injurious to the marine life. When the oil spreads over water, the diffusion of oxygen into water is inhibited. This affects the respiration of fish and other marine life. Oil pollution of sea causes either problems too. Oil is pushed to the shore by the water currents and winds, thereby spoiling the beaches.


Combustion of fuel

The burning of fossil fuels releases a variety of noxious gases and particulate matter into the atmosphere. The major contributors to this atmospheric pollution are coal and oil and natural gas by far is the least offensive of the fossil fuels , One of the major problems with coal and oil is the presence of sulphur. Depending upon the source, the sulphur content can be up to several percent and upon combustion several oxides (particularly sulphur dioxide) are produced. When sulphur dioxide is released into the atmosphere, it combines with water vapour and forms sulphuric acid. It is this sulphuric acid which is injurious to plant and animal life. It has been found that atmospheric sulphuric acid eating the limestone facings of many monuments and public buildings in urban life. Sulphur dioxide is believed to cause cough, shortness of breath and spasm of the larynx. It can cause acute irritation to the membranes of the eyes resulting in excessive flow tears and redness. When absorbed by plants beyond a certain level the plants cells become inactive and are killed, resulting in tissue collapse and drying of leaves. Sulphur dioxide is also known to interfere with the respiratory and photosynthesis in plants.


Energy for KOER html m798592ab.gifThe burning of petrol in internal combustion engines is the major source of carbon monoxide, nitrogen dioxides and hydrocarbons in the atmosphere. In addition, there are large quantities of lead which are released into the atmosphere from high octane petrol used in cars. All these pollutants and the products of the photochemical reactions they undergo in presence of sunlight contribute to the noxious known as smog. There seems at present no escape from the health hazards of smog until some effective way is found to remove the pollutants from the vehicular exhaust gases.


Combustion of fuel - Effects of carbon Dioxide and carbon Monoxide:

The consumption of oxygen and the formation of carbon dioxide are necessary consequences of every combustion process. One may think that this may deplete the world’s supply of oxygen and thus upset the oxygen-carbon dioxide balance that is necessary for plant and animal life.


Carbon dioxide molecules strongly absorb heat radiations emitted from the surface of the earth heated by the sun. By holding back this energy in the earth’s atmosphere, carbon dioxide reduces the heat lost by the earth to space. This is called ‘greenhouse effect’ and because of this, it is argued, the continued burning of fossil fuels will result in a steady increase in the earth’s surface temperature. However, an increasing in the temperature of the earth’s surface and lower atmosphere has the compensating effect of increasing evaporation and cloudiness. Because clouds reflect some of the incident sunlight, increases in cloudiness tend to decrease the surface temperature. Further, the release of particulate matter into the atmosphere from fuel burning increases the number of condensation sites around which water droplets can form. The result is an increase in the amount of rain, hail and thunderstorms which lead to the lowering of the temperature. The amount of carbon dioxide is regulated by the presence of the ocean waters which 60 times as much carbon dioxide as does the atmosphere and absorbs a large fraction of the carbon dioxide released by the burning of fuels. Also, the increased level of carbon dioxide in the atmosphere actually stimulates a more rapid growth of plants. This increased utilization of carbon dioxide further reduces the atmospheric excess. Thus the role of carbon dioxide in influencing the world’s climate is quite a complex one.


Carbon monoxide is another pollutant produced by burning of fossil fuel. It is usually produced when there is insufficient oxygen for burning. It is released into the atmosphere mainly from automobile exhaust gases. But it does not so far constitute a serious environmental problem.


Thermal pollution

The term ‘thermal pollution' basically refers to the detrimental effects of discharges of unwanted heat into the environment. All electricity generating plants produce electricity by driving huge turbine generators with steam. The steam is condensed in a cooling system and is cycled back to the heating unit for reuse. The cooling system can be water that is pumped from some nearby reservoir and discharged back into it, or it can be a cooling tower in which the heat is dissipated into the atmosphere. Both cause thermal pollution. If the heated water is discharged into a static reservoir, such as a lake, the effect can be even more severe. The thermal is generated by the energy producer as well as the energy user. Almost all of the energy we use is eventually converted into heat. Most of this waste is dissipated into the air where it contributes to the general atmospheric heating.


Effects of Nuclear Radiations

Nuclear reactors, unlike the other sources of power, offer a lot of advantage. Nuclear reactors generate electrical power without the smoke and fumes that are characteristic of fossil fuel-burning plants. Also the mining of uranium produces much less degradation of the countryside than the mining of fossil fuels, particularly coal. Nuclear reactors, therefore, offer the prospect of long term relatively clean power. However, nuclear reactors have their own peculiar set of disadvantages, mainly associated with the production of radioactive materials. Some radioactive waste is released into the environment both gases into the atmosphere and in the form of low activity waste such as tritium in cooling water.


All radioactive substances emit harmful radiations, some of which can cause cancer in man and animals and damage the genetic material of the cell, producing long term harmful effects in living organisms. However, modern nuclear reactors are quite safe. An individual living near a nuclear reactor is exposed much less to its emitted radiation than what one gets from X-rays and natural sources.


Energy and the future

The worldwide demand for energy is increasing day by day. The increasing use of modern means of transport-cars, buses, trains, aero planes , ships, etc., the rapid rise in the overall industrialization; the tremendous growth in population, particularly in the last 40 years, are some of the factors that have led to a tremendous spurt in mankind’s energy requirements.


Need for Judicious Use of energy

It follows therefore that mankind has to adopt a judicious approach towards consumption of energy sources to ensure that these are not depleted too fast. This approach needs to be supplemented by optimum utilization of our natural sources. We have, for example, reserves of billions of tones of coal spread across the Bihar, West Bengal and Orissa region. This coal may not be of the best quality, but coal mining in this area can always be stepped up to meet our energy requirements. In India, technology used is coal mining and handling after it is mined is still primitive where mechanical wheels are used in open pit mining. Any improvement in material handling system can lead to a saving of a lot of coal which is otherwise lost.


One source of energy which has remained underutilized is the hydroelectric energy. The subcontinent has many large rivers with substantial hydroelectric potential, much of which still remains unutilized. These can be tapped to provide energy which is clean, renewable and cheap. Large numbers of small hydroelectric power projects across the country over the country over small rivers could also yields a fair amount of energy.


Wind energy has a tremendous scope as alternative source of energy not only in India but the entire region stretching from Afghanistan to Vietnam. Wind electric generators are at present operating successfully in many parts of India. Windmills are also being used for pumping water and this use of windmills should be encouraged. If India develops a system whereby windmills and generators could be manufactured on a large scale, it will really be a tremendous boon to the rural economy of this vast region. Wind energy is a non-polluting, cheap, renewable source of energy.


A substantial portion of our energy requirements is met by firewood. It necessitates felling of trees, resulting in deforestation, soil erosion, and floods. To prevent this and to maintain the stability of forest reserves a massive afforestation programme is necessary. The use of firewood as fuel must be avoided as far as possible by encouraging the use of biogas plants. Benefits accruing from biogas plants are immense and manifold. Biogas plant generate but only substantial economic gains to the country but also help up gradation of the environment. As India is dependent on imported oil for meeting its energy requirements, it would be prudent to reduce the consumption of petroleum products. These are primarily used for road and rail transport. The industry uses a large quantity of petroleum products both as raw material and also as fuel. There is tremendous scope for reducing the consumption of diesel and petrol in cars, trucks and two wheelers by more efficient engine design and maintenance.


It is indeed a good news that India has vast reserves of natural gas which is a very clean source of energy. The Bombay High oilfields contain very large quantities of gas which at present are flared or burnt. Only recently are efforts being made to utilize natural gas commercially, for generating power and production of fertilizer. Especially in the north east. The Dutch and the British have found vast reserves of offshore natural gas and in the process have developed new technology to utilize it.


Minimizing Wastage

Not only have we to adopt a judicious approach to using our energy sources, we have also to lay a great stress on prevention of wastage. Even a casual look at our day-today activities reveals that energy is wasted in many ways. Careless habits, like leaving the lights and fans on when no one is round, keeping the car or scooter engine on while gossiping with a friend on the road, etc. contribute to wastage of energy. We have to know about the various ways in which energy is wasted at home and in industries, and then develop-and encourage others to develop-proper design and also ensure that all machinery is kept well maintained and in proper running condition. This helps save a lot of energy. With the impending energy crisis facing mankind, saving ‘every bit of energy ‘ is of great importance. This saved energy can then be put to some useful ‘use’ in future. WE must remember energy saved is energy produced.


Evaluation:

  1. What is work?When do we say that work is done?
  2. What are kinetic and potential energy?
  3. What are the different forms of energy?
  4. What is power?
  5. What are the units of energy?
  6. What are fossil fuels?How are they formed?
  7. What are the different steps to process the petroleum?
  8. What is Biomass energy? How it is generated?
  9. What are the different sources of non -conventional energy?
  10. What are the different ways of harnessing solar energy?
  11. Name the different non conventional sources of energy.
  12. Name the different storage devices.
  13. What are isotopes? Name some isotopes.
  14. Draw the diagrams of the nuclear reactors-thermal and fast breed
  15. How are fossil fuels threatening us?
  16. What are the effects of Carbon Dioxide and Carbon Monoxide?
  17. How are nuclear radiations affect out environment?
  18. What is the need for judicious use of available energy?
  19. List some steps to minimize energy wastage

Additional web resources

  1. [[5]]
  2. File:Energy for KOER html m145a4ee8.gifFile:Energy for KOER html mb374f76.gif[[6]]
  3. [[7]]
  4. web.mit.edu/8.02t/www/materials/modules/ReviewD.pdf – This review document summarizes the law of conservation of energy very clearly
  5. [[8]]
  6. [[9]]
  7. [[10]]
  8. www.sciencejoywagon.com/physicszone/05work-energy/
  9. www.technologystudent.com/energy1/less4.html
  10. [[11]]
  11. [[12]]
  12. [[13]]
  13. [[14]]
  14. www.indiacore.com/.../kssidhu-non-conventional-energy-resources.pdf
  15. [[15]]
  16. [[16]]
  17. uw.physics.wisc.edu/~himpsel/wires.html
  18. hyperphysics.phy-astr.gsu.edu/hbase/nucene/fission.html
  19. phet.colorado.edu/en/simulation/nuclear-fission
  20. www.whatisnuclear.com/articles/nucreactor.html
  21. [[17]]
  22. [[18]]
  23. [[19]]
  24. www.whatisnuclear.com/articles/nucreactor.html
  25. www.westinghousenuclear.com/.../WhatIsNuclearEnergy.shtm
  26. www.indianuclearenergy.net
  27. video.nationalgeographic.com/video/.../energy.../alternative-energy.html
  28. en.wikipedia.org/wiki/''Waste''_minimisation - CachedSimilar
  29. www.youtube.com/watch?v=FBTXQV7GKow
  30. www.streetdirectory.com/.../'energy'-'crisis-in-india'-aouac.html - CachedSimilar




Energy for KOER html m798592ab.gifKeywords – Work, Energy, Power, Kinetic Energy, Potential Energy, Law of Conservation of Energy, Thermodynamics, Biomass, Fossil Fuel, Combined Cycle Power Generation