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Page 1: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS
Page 2: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS
Page 3: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS
Page 4: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS
Page 5: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

WORK POWER ENERGY COLLISIONS

Page 6: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

What is Work?

Work Done by a Constant Force

Dimensions and Units of Work

Nature of Work Done

Work Done by a Variable Force

Conservative and Non-Conservative Forces

Page 7: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

What is Work?

Work is said to be done when a force applied on a body

produces some displacement in it in any direction except in a direction perpendicular to the direction of the force.

For example, when a person carrying a load moves on a horizontal road, he is not performing any work as distance moved is in a direction perpendicular to the force

applied.

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When a constant force F acting on a body produces a displacement s in the body, then work done by the force(W) is the dot product of force and displacement i.e.

W = F. sIf is smaller angle between F and s, then W = Fscos

Page 9: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

When displacement is produced in

the direction of application of force then = 0°.cos = cos 0° = 1 W = Fs

Thus work done by a constant force is the product of force and displacement, when the two vectors F and s are in the same direction.

Work is a scalar quantity i.e. it has magnitude only and no direction.

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WORK DONE IN RECTANGULAR CARTESIAN CO-ORDINATE SYSTEM

F = i Fx + j Fy + k Fz

s = i x + j y + kzW = F . s

W = ( i Fx + j Fy + k Fz ) . ( i x + j y + kz )

W = x Fx + y Fy + z Fz

^ ^ ^^ ^ ^

^ ^ ^ ^ ^ ^

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DIMENSIONS OF WORK

As work = force * distance W = (M1L1T-2) * L = [ M1L2T-2 ]

UNITS OF WORK

Joule Work done is said to be 1joule,when a force of 1 newton moves a body actually through a distance of 1metre in the direction of applied force.

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Erg Work done is said to be 1erg,when a force of 1dyne moves a body actually through a distance of 1cm in the direction of applied force.

RELATION BETWEEN JOULE AND ERG

As 1 joule =1N * 1m * cos0°

1 J = 105dyne * 102cm * 1 1 joule = 107erg

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(1) Positive Work As W = F. s = Fscos

when is acute (<90 °) ,cos is positive.Hence work done is positive.

Example – When a body falls freely underthe action of gravity.

(2) Negative Work As W = F. s = Fscos

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when is obtuse (>90 °) ,cos is negativeHence work done is negative.

Example – When brakes are applied on moving vehicle.

(3) Zero Work When = 90 °,

cos = cos 90 °= 0 Hence work done is zero.

Example – When a coolie carrying some load on his head moves on horizontal platform.

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Work Done by a Variable Force

Work done in moving R to S = F * dx

= Area of PQRSWork done in moving x1 to x2

= x1Fdx

W = x1Fdx = Area of ABCD

Hence work done by a variable force is numerically equal to the force curve and the displacement axis.

x2

xBxAO A B

C

DSR

PQ

F(x)

x

x2

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Power – It is defined as the rate at which the body can do the work, i.e.

Power = Rate of doing work = Work / Time

= W / t = ( F. s )/ t P = F.v

Instantaneous Power – Power at a particular instant of time.P = dw / dt

Page 17: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

DIMENSIONS OF POWER P = W / t = [M1L2T-2] / [T1] = [M1L2T-3]

UNITS OF POWER

The SI unit of power is watt. From P = W / t , 1 Watt = 1 joule / 1 sec i,e 1W = 1Js-1

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Hence power of an agent is said to be onewatt, if it can do one joule of work in 1 second.

Bigger units of power are – 1 kilo watt = 1000 watt 1 kW = 103

1 mega watt = 1,000,000 watti.e. 1MW = 106 W Absolute unit of power in c.g.s. system is 1 erg s-1

Another popular unit of power is horse power(h.p). 1 h.p = 746 W

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Conservative and Non-Conservative Forces

Conservative forces – If the amount of work done aganist the force depends on initial and final position of body moved the force is called conservative forces.

Examples :- Gravitational force, Magnetic force.

Work done against force does not depend on the path of the body.

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We can explain that gravitational force is conservative with the help of following example :-

Case(a) ~ W = F * h = mgh

Case(b) ~ W = mgh1 + mgh2

= mg ( h1+h2 ) = mgh

hm

h1

h2

D C

BA

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Case(c) ~ W = mgh

Case(d) ~ W = F * l = mgsin * l = mg * h / l * l

= mghmgsin

h

mgmgco

s

FR

Page 22: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

Non-Conservative forces – If work done depend on the path taken by body in motion, the force is called non-conservative force.In this case, mechanical energy is not constant.

Example :- frictional force depend on length of path.

Work done in lifting a body against gravity is independent of path taken only depends on initial and final position of the object. So, the gravitational force is conservative.

Page 23: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

What is Power? Dimensions and

Units of Power

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What is Energy? Types of Energy Different forms of Energy Work Energy Theorem Transformation of Energy Principle of Conservation

of Energy

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What is Energy?Energy of a body is defined as

the capacity or ability of the body to do the work .

DIMENSIONS OF ENERGY The dimensions of energy are [M1L2T-2] .

UNIT OF ENERGY In SI, absolute unit of energy is joule

and in c.g.s. system, the absolute unit of energy is erg.

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TYPES OF ENERGY

Energy is of several types e.g. mechanical energy, heat energy, light energy, electric energy, chemical energy, sound energy, nuclear energy, solar energy and so on. But we shall confine ourselves to the study of mechanical energy which is of two types :- KINETIC ENERGY

POTENTIAL ENERGY

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KINETIC ENERGYThe kinetic energy of a body is the energy possessed by the body by virtue of its motion.

For example:- A bullet fired from gun. EXPRESSION FOR KINETIC ENERGY From v2 – u2 = 2as

As u = 0 v2 = 2as

a = v2 / 2s .......(1)

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As , F = maFrom (1) ,

F = m( v2 / 2s) Work done = Force * Distance W = mv2 / 2s * s W = ½mv2

This work done on the body is a measure of kinetic energy of the body , K .E . of body = W = ½mv2

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POTENTIAL ENERGYThe potential energy of a body is defined as the energy possessed by the body by virtue of its position.

Example – A compressed spring.

Three important types of potential energy are : Gravitational potential energy Elastic potential energy Electrostatic potential energy

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POTENTIAL ENERGY OF THE SPRING

(c) Compressed spring

(b) Stretched spring

(a) Unstretched spring

x

x

FR

FR

FR=0

Fexternall

Fextern

al

Page 31: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

Let us consider smooth mass m attached to a spring whose one end is rigidly fixed to a wall as shown in the figure.

For a small stretch or compression, spring obeys Hook’s law,

Restoring force stretch or compression-F x - F = kx

where k is the spring constant.

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During the elongation and compression of spring, some work is done and that work is stored in the spring as its potential energy.

Work done = Area of AOB = ½ .x.F = ½ .x.kxW = kx2 / 2

Force

x(extension)BO

A

Page 33: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

CURVES FOR KINETIC ENERGY AND POTENTIAL

ENERGY

DISPLACEMENT

ENERGYTOTAL ENRGY

P.E.

K.E.

X=-XO X=0 X=XO

At X = ±XO, P.E. is maximum.

At X = 0, K.E. is maximum.

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According to this principle, work done by a forces in displacing a body measures the changes in kinetic energy of the body.

DERIVATION OF WORK ENERGY THEOREM

Suppose , m = mass of the body, u = initial velocity of the body , F = force applied on the body in the

direction of motion,

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ds = small displacement of the body in the direction of F.

dW = F.ds = F ds cos00

dW = F ds = m a ds {F = ma } = m (dv / dt) ds { a = dv/dt } = m (ds / dt) dv dw = m v dv { v = ds/dt } Total work done by the force in increasing

the body from u to v is W = mvdv = m [v2/2]v

= ½m(v2-u2)

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W = ½mv2 - ½mu2

= Final K.E - Initial K.E W = change in K.E of the body

Hence work done by a force is a measure of change in K.E of a body, which proves the work energy principle .

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Transformation of Energy

It is a phenomenon of energy from one form to other. We come across such changes in day –to - day life .

For example :-

In an electric bulb, electric energy is converted into light energy and heat energy.

In an electric iron , electric heater ,geyser etc., electric energy is converted into heat energy

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In an electric fan , electric motor, electric energy is converted into mechanical energy .

In a hydroelectric power station , potential energy of water is converted ultimately into electric energy.

In a heat engine , chemical energy from coal / oil is converted into mechanical energy.

In a nuclear reactor , mass is being converted into energy .

In the sun and other stars , mass is being converted into energy , and so on .

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Principle of Conservation of Energy

According to this principle , the sum total of energy of all kinds in an isolated system remains constant at all times . This means that energy can neither be created nor destroyed.

PROOF OF THIS PRINCIPLE :-

Let m be the mass of the body held at A , at a height h above the ground.

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As the body is at rest at A , therefore,At A : K.E of the body = 0

P.E of the body = mgh, Total Energy = K.E + P.E. = 0 + mgh

E1 = mgh ......(i)

C

B

A

h

(h – x)

x

GROUND

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Let the body be allowed to fall freely under

gravity , when it strikes the ground at C with a velocity v .

From v2 - u2 = 2as

v2 – 0 = 2gh v2 = 2gh ...........(ii)

At C : K.E. of the body = ½ mv 2

= ½ m (2gh) = mgh P.E. of the body = mgh = mg(0) = 0 Total energy of the body = K.E. + P.E E2 = mgh + 0 = mgh ......(iii)

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In free fall, let the body cross any point B with a velocity v1, where AB = x

From v2 –u2 = 2as v12 - 0 = 2gx v12 = 2gx .............(iv) At B : K.E. of the body = 1/2mv12

= ½ m (2gx) = mgx

Height of the body at B above the ground = CB = ( h – x )

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P.E. of the body at B = mg(h - x ) Total energy of the body at B = K.E. + P.E. E3 = mgx + mg ( h – x ) = mgx + mgh – mgx = mgh ........(v) From (i) , (iii) , (v) :-

E1 = E2 = E3 = mgh

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HEAT ENERGY :- It is the energy possessed by a body by virtue of random motion of the molecules of the body .

INTERNAL ENERGY :- It is the energy possessed by the body of particular configuration of its molecules and also their random motion .

ELECTRIC ENERGY :- It arises on account of work required to be done in

DIFFERENT FORMS OF ENERGY

Page 45: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

moving the free charge carriers in a particular direction through a conductor .

CHEMICAL ENERGY :- chemical energy of a body , say a chemical compound is the energy possessed by it by virtue of chemical bonding of its atom .

NUCLEAR ENERGY :- It is the energy obtainable from an atomic nucleus .

Page 46: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

?What is collision Coefficient of Restitution Types of collision

Page 47: WORK WORK  POWER POWER  ENERGY ENERGY  COLLISIONS COLLISIONS

?WHAT IS COLLISION

A collision is defined as an isolated event in which two or more colliding bodies exert relatively strong forces on each other for a relatively short time.

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Types of collision

Collisions between particles have been divided broadly into two types :

Elastic collisions Inelastic collisions

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Elastic Collisions

What is elastic collision? Elastic Collision in One

Dimension Elastic Collision in Two

Dimension

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Elastic CollisionsA collision in which there is absolutely no loss of kinetic energy is called an elastic collision.

For example – Collision between atomic and sub atomic particles.

CHARACTERISTICS OF AN ELASTIC COLLISION ARE :-

The linear momentum is conserved. Total energy of the system is

conserved.

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The kinetic energy is conserved.

The forces involved during elastic collisions must be conservative forces.

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Inelastic collisions

A collision in which there occurs some loss of kinetic energy is called an inelastic collision.

For example - If a meteorite collides head on with earth, it becomes buried in earth.CHARACTERISTICS OF AN ELASTIC COLLISION ARE :-

The linear momentum is conserved.

Total energy of the system is conserved.

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The kinetic energy is conserved.

The forces involved during elastic collisions must be conservative forces.

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Coefficient of Restitution

It is defined as the ratio of relative velocity of separation after collision to the relative velocity of approach before collision. It is represented by ‘e’. e

=

relative velocity of separationrelative velocity of approach

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v2 - v1

u1 - u2

where u1 , u2 are velocities of two bodies before collision and v1 , v2 are their respective velocities after collision.For a perfectly elastic collision, relative velocity of separation after collision is equal to relative velocity of

e =

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approach before collision. e = 1For a perfectly inelastic collision, relative velocity of separation after collision = 0. e = 0For all other collisions, e lies between 0 and 1 i.e. 0 < e < 1.

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Elastic Collision in One Dimension

B B

B

A A

A

u2u1

m2m1 m1

m1

m2

m2

v2v1

BEFORE COLLISION DURING COLLISION

AFTER COLLISION

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Applying the law of conservation of momentum :- Momentum before = Momentum after collision collision m1u1 + m2u2 = m1v1 + m2v2 .... (1)

or m1 ( u1 – v2 ) = m2 ( v2 – u2 ) .......(2)

Applying the law of conservation of energy :- Total K.E. of two = Total K.E. of two balls before collision balls after collision

½m1u1 + ½ m2u2 = ½ m1v1 + ½ m2v2 ....(3)2 2 2 2

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or m1 ( u1 – v2 ) = m2 ( v2 – u2 ) .....(4)

Dividing (4) by (2) , we get :-

m1 ( u1 – v2 ) = m2 ( v2 – u2 ) m1 ( u1 – v2 ) m2 ( v2 – u2 ) u1 + v1 = v2 + u2

u1 – u2 = v2 – v1 .....(5)

Relative velocity Relative velocity of approach = of separation before collision after collision

From (5), v2 – v1

u1 – u2

2 2 2 2

2 2 2 2

= e = 1

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Calculation of velocities after collision :-

VELOCITY OF A :From (5), v2 = u1 + v1 – u2

Putting this value in (1) : - m1u1 + m2u2 = m1v1 + m2(u1 + v1 – u2)

m1u1 + m2u2 = m1v1 + m2u1 + m2v1 – m2u2

v1 = ( m1u1 + 2m2u2 - m2u1 ) / ( m1 + m2 ) ..........(6)

VELOCITY OF B :Putting this value of v1 in (5) : -

v1 =u1 ( m1 - m2 ) + 2m2u2

m1 + m2

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..........(7)

1) When masses of two bodies are equal :-m1 = m2 = m

From (6), v1 = 2mu2 / 2m = u2

i.e. velocity of A = velocity of B after collision before collision

u1 ( m1 - m2 ) + 2m2u2 m1 + m2

v2 = u1 – u2 +

v2 = ( u1 – u2 ) ( m1 - m2 ) + u1 ( m1 - m2 ) + 2m2u2 m1 + m2

v2 = 2m1u1 + u2 ( m2 – m1 )

m1 + m2

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From (7), v2 = 2mu1 / 2m = u1

i.e. velocity of B = velocity of A after collision before collisionHence after collision , velocities are just interchanged.

2) When the target body B is initially at rest :-i.e. u2 = 0

From (6), v1 = ( m1 - m2 ) u1 / (m1 + m2) .........(8)

From (7), v2 = 2m1u1 / (m1 + m2) .........(9)

THREE CASES ARISE FURTHER:(a) When masses of two bodies are equal :-

i.e. m1 = m2

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From (8), v1 = 0

From (9), v2 = 2m1u1 / 2m1 = u1

i.e. body A comes to rest and body B starts moving with the initial velocity of A.

(b) When body B at rest is very heavy :- i.e. m2 >> m1

m1 can be ignored compared to m2.

Putting m1 = 0 in (8) and (9) , we obtain :-

v1 = - m2u1 / m2 = -u1

v2 = 0

Hence when a light body A collides against a heavy body B at rest then A rebounds with its own velocity and B continues to be at rest.

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(c) When body B at rest has negligible mass :- i.e. m2 << m1

m2 can be ignored compared to m1.

Putting m2 = 0 in (8) and (9) , we obtain :-v1 = m1u1 / m1 = u1

v2 = 2m1u1 / m1 = 2u1

Hence when a heavy body A undergoes an elastic collision with a light body B at rest, the body A keeps on moving with the same velocity of its own and the body B starts moving with double the initial velocity of A.

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Elastic Collision in Two Dimension or Oblique

Collision

m1

A

••B

B

X

Y

v1

m2

u2

v2

u1

A

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As the collision is elastic, kinetic energy is conserved. Total K.E. after = Total K.E. before

collision collision or ½m1u1 + ½ m2u2 = ½ m1v1 + ½ m2v2........(10)

m1u1 + m2u2 = m1v1 + m2v2 .........(11)

As linear momentum is conserved in elastic collision, therefore, along X-axis,

total linear momentum = total linear momentum after collision after collision

m1v1cos + m2v2cos = m1u1 + m2u2 ........(12)

Along Y-axis,m1v1sin - m2v2sin = 0 .......(13)

2 222

2 2 2 2

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From three equations (11), (12) and (13), we have to calculate four variables v1, v2, and , which is not possible. We have, therefore, to measure experimentally any one parameter.

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MRS CHITRA JOSHIPGT (PHYSICS)KV FRI DEHRADUN

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