WORK POWER & ENERGY

IIT- P-WPE

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WORK, POWER & ENERGY

WORK, POWER & ENERGY

Kinetic and potential energy; Work and Power, Conservation of mechanical energy, work energy principle.

WORK :

.

When a force is applied at a point and the point gets some displacement along the direction of force then work is said to be done by the force. The work done, W by a constant

force →_F when its point of application undergoes a displacement →_S is measured as

W =

_F

→. →

_S

= |→_F | | →_S | cosθ

Where θ is the angle between →_F and →_S . Work is a scalar quantity and its SI unit is N-m or

joule (J).

Only the component (Fcosθ) of the force F which is along the displacement contributes

to the work done. If →_F =

x

F

→

i$

+

F

y

→

$j

+

_F

→_z

_k

$

and →_S = ∆x

_i$

+ ∆y

$j

+ ∆z

_k

$

then W = →_F .

_S

→ = Fx∆x+Fy∆y+Fz∆z

Positive and Negative work : The work is said to be positive if the angle θ is acute (θ

< 900_{) and negative if the angle θ is obtuse (θ > 90}0_{). If the angle between} →

F and →S is 900

then work done by the force is zero.

If the force is variable then the work done by the variable force is given by dW =→_F ._dS→

or W =

∫

→ → 2 1 S S

dS

.

F

Work depends on frame of reference. With change of frame of reference displacement may change, so the work done by a force will be different in different frames.

Illustration – 1 :

A particle of mass 2 kg moves under the action of a constant force →_F =

(

5i 2 j$− $

)

N. If

its displacement is 6

$j

m. What is the work done by the force→_F ?

Solution :

The work done →_F . →_x

=

(

5i 2 j

$

−

$

)

.

_{6 j}

$

= - 12 Joule

Illustration – 2 :

A load of mass m = 3000 kg is lifted by a rope with an acceleration a = 2 m/s2_{. Find the}

work done during the first one and a half seconds from the beginning of motion.

Solution :

The height to which the body is lifted during the first 't' second is h = 2 1 at2 _{tension in} the rope T = mg + ma

∴

Work done = T.h = m(g + a)       2 2 1 at = 3000 (10 + 2) _ 2

( )

152_ 2 1 . x x = 81 KJ

WORK DONE BY A SPRING FORCE :

Whenever a spring is stretched or compressed, the spring force always tend to restore it to the equilibrium position. If x be the displacement of the free end of the spring from its

equilibrium position then, the magnitude of the spring force is FS = - kx

The negative sign indicates that the force is restoring.

The work done by the spring force for a displacement from xi to xf is given by

Ws = −

∫

f x i x kxdx ⇒ Ws =

(

2 2

)

2 1 i f x x k − −

WORK DONE BY FRICTION :

Work done by friction may be zero, positive or negative depending upon the situations:

 When a block is pulled by a force F and the block does not move, the work done by

friction is zero.

 When a block is pulled on a stationary surface, the work done by the kinetic friction is

negative.

 When one block is placed on another block and is pulled by a force then friction force

does negative work on top block and positive work on the lower block

WORK DONE BY GRAVITY :

IIT- P-WPE 3 → S= ∆x

i$

+ ∆y

$j

+ ∆z

k

$

∴ Work done by gravity is Wg = →F_g. →_S = - mg ∆y

∆y =

y

f

−

y

i = - h

∴ Wg = + mgh

If the block moves in the upward direction, then the work done by gravity is negative

and is given by Wg = - mgh.

DEPENDENCE OF WORK ON FRAME OF REFERENCE :

Work depends upon the frame of reference from where it is calculated. As the displacement as well as force, depends upon the different frames of reference. Therefore, the work also changes.

For example :- If you calculate work from a non inertial frame work due to pseudo force has to

be included.

CONSERVATIVE AND NON CONSERVATIVE FORCES :

In Conservative force field the work done by the force is independent on path followed

and depends only on initial and final co-ordinates. Such forces are known as Conservative forces.

Examples are gravitational, electrostatic forces.

If the work done depends on path followed. Such forces are called non- Conservative forces. Example is frictional force.

Illustration – 3 :

A train is moving with a constant speed "v". A box is pushed by a worker applying a force "F" on the box in the train slowly by distance "d" on the train for time "t". Find the work done by "F" from the train frame as well as from the ground frame.

Solution :

As the box is seen from the train frame the displacement is only 'd' if the force direction is same as the direction of motion of the box.

Then the work done = F.d = Fdcos00 _{= Fd}

= Fdcos1800 _{= -Fd (if the displacement on the train is opposite}

to 'F')

As the box is seen from ground frame,

the displacement of the box = vt + d (if the displacement is along the direction of motion of the train )

= d - vt (if the displacement is opposite to direction of motion of the train)

Illustration – 4 :

A block is (mass m) placed on the rough surface of a plank (mass m) of

coefficient of friction "µ" which in turn is placed on a smooth surface. The block

is given a velocity v0 with respect to the plank which comes to rest with respect

to the plank. Find the

a) The total work done by friction in the plank frame.

b) The work done by friction on the smaller block in the plank frame. c) Find the final velocity of the plank

Solution :

The acceleration of the plank = Friction force applied by the block on the plank / mass of the plank.

g m mg a_p =µ =µ

(a) Pseudo force acting on the block = µg (back wards)

Force of friction is µmg ( acting backwards)

From the plank frame time needed to stop the block is given by

0 = V0 +at

(

a=−2µg

)

⇒ t = g V µ 2 0

Velocity of the plank during this time is Vp =up+apt

= 2 2 0 0 V g V g = µ µ

Displacement of the block = S = _a V_g

V V µ =             ×       − 8 3 2 2 02 2 0 2 0

Work done by friction on the block =

( )

1

8 3 2 0 ₋ µ µ = π g V . mg cos . S . F = 2₀ 8 3_mv −

(b) From the Plank frame

Work done by friction on smaller block = -µmgl

g 2 V 0 2 0 µ − − =  _⇒

2

mV

g

2 0

=

µ



⇒ work done by friction from the Plank frame =

2

mV

2

0

−

(c) Final velocity of the block

m

m

v

0 mg µ p ma m

IIT- P-WPE

5

= Velocity of the plank =

2

0

V

WORK ENERGY THEOREM :

Now we have to study which physical quantity changes when work is done on a particle. If a constant force F acts through a displacement x, it does work W = Fx



2 2 i f v v = + 2 ax ∴ W =

(

)

2 2 2 i f mv −v ₌ 2 1 mv_f2- 2 1 mv_i2 The quantity k = 2 1

m v2 _{is a scalar and is called the kinetic energy of the particle. It is}

the energy posses by the particle by virtue of its motion.

Thus the equation takes the form W=Kf −Ki =∆K

The work done by a force changes the kinetic energy of the particle. This is called the work -Energy Theorem.

Illustration – 5 :

The velocity of an 800 gm object changes from _v→₀ = 3

_i$

- 4

$j

to →

f

v = -6

$j

+ 2

k

$

m/s.

What is the change in K.E of the body?

Solution : Here m = 800gm = 0.8 kg → o v _{= 3}2₊

( )

₋₄2 _{= 5} v→f = (−6)2+( )22 = 40

∴

change in K.E = 2 1 x 0.8 _        −→ → 2 0 2 v vf = x 0.8x

(

40 25

)

6J 2 1 _{− =} Illustration – 6 :

The coefficient of sliding friction between a 900 kg car and pavement is 0.8. If the car is moving at 25 m/s along level pavement, when it begins to skid to a stop, how far will it go before stopping?

Solution :

Here m = 900kg µ = 0.8, v = 25 m/s S =?

K.E = work done against friction 2

2 1 mv = F.s = µ N.s = µmgs ⇒ s = g v µ 2 2 =

( )

10 8 0 2 252 x . x ~ 39 m

Illustration – 7 :

An object of mass 10kg falls from rest through a vertical distance of 20m and acquires a

velocity of 10 m/s. How much work is done by the push of air on the object? (g = 10 m/s2₎

Solution :

Let upward push of air be F

∴

The resultant downward force = mg - F

As work done = gain in K.E

(mg - F) x S = 2 2 1 mv

∴

(10 x 10 - F) x 20 = 2 1 x 10 x (10)2_{⇒ F = 75 N}

∴ Work done by push of air = 75 x 20 = 15 Joule

This work done is negative.

POTENTIAL ENERGY :

Potential energy of any body is the energy possessed by the body by virtue of its position or the state of deformation. With every potential energy there is an associated conservative force. The potential energy is measured as the magnitude of work done against the associated conservative force

du = -F.dr

for example :

(i) If an object is placed at any point in gravitational field work is to be done against

gravitational field force. The magnitude of this work done against the gravitational force gives the measure of gravitational potential energy of the body at that position which is U = mgh. Here h is the height of the object from the reference level.

(ii) The magnitude of work done against the spring force to compress it gives the measure

of elastic potential energy, which is U = 2 1

k x2

(iii) A charged body in any electrostatic field will have electrostatic potential energy. The

change in potential energy of a system associated with conservative internal force as

U2-U1= - W=−

∫

2 1

F. dr

CONSERVATION OF MECHANICAL ENERGY :

Change in potential energy ∆U = - WC where WC is the work done by conservative forces.

From work energy theorem Wnet = ∆k

IIT- P-WPE

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is subjected to only conservative forces then Wnet = WC = ∆k

∴

∆ U = - ∆k ⇒ ∆U + ∆k = 0

The above equation tells us that the total change in potential energy plus the total change in kinetic energy is zero, if only conservative forces are acting on the system.

∴

∆(k+U) = 0 or ∆E = 0 where E = k + U

∴

When only conservative forces act, the change in total mechanical energy of a

system is zero. i.e if only conservative forces perform work on and within a system, the total mechanical energy of the system is conserved.

∴

kf + Uf - (ki + Ui) = 0

⇒ kf + Uf = ki + Ui



∆E = 0, integrating both sides E = constant.

Illustration – 8 :

A projectile is fired from the top of a 40m. high cliff with an initial speed of 50 m/s at an unknown angle. Find its speed when it hits the ground.

Solution :

Taking ground as the reference level we can conserve the mechanical energy between the points A and B

∴

∆ (K + U) = 0 ⇒ Ki + Ui = Kf + Uf ⇒ 2 1 mv2 _{+ mgH =} 2 1 mv' 2 _{+ 0} ⇒ 2 1 (50)2 _{+ 40 x 10 =} 2 1 v' 2 ⇒ (1250 + 400) x 2 = v' 2 ⇒ v' 2 _{= 3300} v' ~ 58 m/s

POWER :

.

Power is defined as the rate at which work is done. If an amount of work ∆W is done in a

time interval ∆t, then average power is defined to be

Pav =

t W

∆ ∆

The S.I. unit of power is J/S or watt (W). Thus 1 W = 1 J/S

The instantaneous power is the limiting value of Pav as ∆t

→

0 that is P =

dt dW

Instantaneous power may also be written as P = ₌→F.→v

dt

dW _{Since work and energy are}

' v H A _θ v B

closely related, a more general definition of power is the rate of energy transfer from one body to another, or the rate at which energy is transformed from one form to another, i.e. P =

dt dE

.

Illustration – 9 :

A car of mass 500 kg moving with a speed 36km/hr in a straight road unidirectionally doubles its speed in 1 minute. Find the average power delivered by the engine.

Solution :

Its initial speed V1 = 10 m/s then V2 = 20 m/s

∴

∆k = 2 1 m ₂2 ₁2 2 1 mv v −

∴

Power delivered by the engine

P =

(

)

t

v

v

m

t

K

∆

−

=

∆

∆

₂

1

22 12 =

(

)

60

10

20

500

2

1

_{2 2}

−

x

= 1250 W.

MOTION IN A VERTICAL CIRCLE :

A particle of mass 'm' is attached to a light and inextensible string. The other end of the sting is fixed at O and the particle moves in vertical circle of radius 'r' equal to the length of the string as shown in the fig. At the point P, net radial force on the particle is

T-mg cosθ. ∴ T - mg cosθ = r mv2 ⇒ T = mg cosθ + r mv2

The particle will complete the circle if the string does not slack even at the highest point

(θ = π). Thus, tension in the string should be greater than or equal to zero (T > 0) at θ = π for

critical situation T = 0 and θ = π

∴ mg =

R

mv

2min _⇒ 2 min v = gR ⇒ v_min = gR

Now conserving energy between the lowest and the highest point

O T P θ θ cos mg θ sin mg

IIT- P-WPE 9 2 1

_{( )}

R mg mv mu_{min min} 2 2 1 ₂ 2 _{= +} ⇒ u_min2 =gR+4gR =5gR gR u_min = 5

If u_min ≥ 5gR the particle will complete the circle. At u = 5gR ,velocity at highest

point is v = gR and tension in the string is zero.

If u < 5gR , the tension in the string become zero before reaching the highest point and

at that point the particle will leave the circular path. After leaving the circle the particle will follow a parabolic path.

Above conditions are applicable even if a particle moves inside a smooth spherical shell of radius R. The only difference is that the tension is replaced by the normal reaction N.

Illustration – 10 :

A heavy particle hanging from a fixed point by a light inextensible string of length l is

projected horizontally with speed g. Find the speed of the particle and the inclination of

the string to the vertical at the instant of the motion when the tension in the string is equal to the weight of the particle.

Solution :

Let T = mg at an angle θ as shown in figure

h = l (1 - cosθ)

Conserving mechanical energy between A and B 2 1 mu2 ₌ 2 1 mv2 _{+ mgh} ⇒ u2 _{= v}2_{+ 2gh ⇒ v}2 _{= u}2 _{- 2gh …. (i)} T - mg cosθ =  2 mv ⇒ T= mg cosθ +  2 mv ⇒ mg = mg cos θ +  2 mv ⇒ v2 _{= gl (1- cosθ) ……. (ii)}

From (i) and (ii) u2 _{- 2gl (1 - cosθ) = gl (1 - cosθ)}

⇒ cosθ = 3 2 ⇒ θ = cos-1       3 2

putting the value of cosθ in equation …… (ii)

v2 _{= gl }      − 3 2 1 = 3  g ⇒ v = 3  g

Equilibrium :As we have studied earlier a body is said to be in translational equilibrium if net

θ A u= g θ cos mg θ sin mg B h • • •

force acting on the body is Zero. Fnet = 0

∴ If the forces are Conservative F =

-dr dU

⇒ 0

dr dU ₌

∴ At Equilibrium slope of U and r graph is Zero (or) Potential energy either

maximum or minimum or constant at that position. At the stable equilibrium position P.E is minimum At the unstable equilibrium position P.E is maximum

Illustration – 11 :

The P.E of a Conservative system is given as U = 10 + (x-2)2_{. Find the equilibrium}

position and discuss type of equilibrium.

Solution : For Equilibrium F = 0 ∴ F = - 2(x 2) 0 dx dU _{=− − =} ⇒ x = 2 and 0 dx U d 2 2 <

∴ it is Stable equilibrium position at x= 2 and P.E at that position is 20 units.

* * * *

WORKED OUT OBJECTIVE PROBLEMS :

.

Example : 01

A particle moves with a velocity 5

_i$

- 3

$j

+ 6

_k

$

m/s under the influence of a constant

force →_{F =}

(

10 i 10 j 20 k

$

+

$

+

$

)

N. The instantaneous power applied to the particle is

A) 200 J/S B) 40 J/S C) 140 J/S D) 170 J/S

Solution :

P = →_{F .V}→ = (5

_i$

-

_{3 j}

$

+6

_k

$

) . (10

_i$

+ 10

$j

+20

_k

$

) = 50 - 30 + 120 = 140 J/S

IIT- P-WPE

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A 15 gm ball is shot from a spring gun whose spring has a force constant of 600 N/m. The spring is compressed by 5 cm. The greatest possible horizontal range of the ball for this compression is (g = 10 m/s2₎ A) 6.0 m B) 12.0 m C) 10.0 m D) 8.0 m Solution : R max = g u2 ₌           mg mu 2 2 1 2 ₌ mg kx mg kx 2 2 2 2 1 =           _      2 _{= kx}2 2 1 mu 2 1  =

(

)

m x . . 10 10 015 0 05 0 600 2 ₌ .

[Note : The actual value of 'u' will be less than the calculated value as some part of 1/2kx2 _{is used up in}

doing work against gravity when the spring regains its length]

Example : 03

Force acting on a particle is (2

_i$

+ 3

$j

) N. work done by this force is zero, when a

particle is moved on the line 3y + kx = 5 Here value of k is

A) 3 B) 2 C) 1 D) 4

Solution :

Force is parallel to the line y = 3/2 x + c

and the given line can be written as y =

3 5 3 +

−k x as the work done is zero

∴ force is perpendicular to the displacement

∴      −       3 2 3 k = - 1 ⇒ k = 2 Example : 04

Power supplied to a particle of mass 2 kg varies with time as p = 2

3_{t watt. Here 't' is in} 2

second. If velocity of particle at t = 0 is v = 0. The velocity of particle at time t = 2 second will be A) 1 m/s B) 4 m/s C) 2 m/s D) 2 2 m/s Solution : kf - ki =

∫

2 0 dt P _⇒ 2 1 mv2 ₌

∫

2 02 3 t2 _{dt ⇒ v}2 ₌ 2 0 3 2__     t



m = 2 kg ⇒ v = 2 m/s

Example : 05

A particle of mass 'm' is projected with velocity 'u' at an angle θ with horizontal. During

the period when the particle descends from highest point to the position where its velocity

vector makes an angle θ/2 with horizontal, work done by the gravity force is

A) 1/2 mu2 _tan2 _{θ/2 B) 1/2 mu}2 _tan2_θ

C) 1/2 mu2 _cos2_{θ tan}2_{θ/2 D) 1/2 mu}2 _cos2_{θ/2 sin}2 _θ

Solution :

As horizontal component of velocity does not change v cos θ/2 = ucos θ

v = 2 θθ cos cos u Wgravity = ∆ K = 2 1 mv2 _- 2 1 m (u cosθ)2 = 2 1 mu2 _cos2_{θ tan}2 2 θ Example : 06

A body of mass 1 kg thrown upwards with a velocity of 10 m/s comes to rest

(momentarily) after moving up 4 m. The work done by air drag in this process is (g = 10 m/s2₎

A) 10 J B) - 10 J C) 40 J D) 50 J

Solution :

From work energy theorem Wgr + Wair drag = ∆ k

⇒ - mgh + Wair drag = 0 - 2 1 mu2 ⇒ Wair drag = mgh - 2 1 mu2 _{= (40 - 50) J = - 10 J} Example : 07

The potential energy of particle of mass 'm' is given by U = 2 1

kx2 _{for x < 0 and U = 0}

for x > 0. If total mechanical energy of the particle is E. Then its speed at x = k E 2 _is A) zero B) M E 2 C) m E _D) m E 2 Solution :

Potential energy of particle at x = k E 2 _{is zero} ∴ K.E = E θ 2 / θ θ cos u V u

IIT- P-WPE 13 ⇒ 2 1 mv2 _{= E or v =} m E 2 Example : 08

A block is suspended by an ideal spring of force constant k. If the block is pulled down by applying a constant Force 'F' and if maximum displacement of block from its initial position

of rest is δ then A) K F < δ < K F 2 B) δ = K F 2

C) Work done by force F is equal to Fδ D) Increases in energy stored in

spring is 2 1

kδ2

Solution :

If the mass of the hanging block be 'm' then elongation of spring is k mg

.

Due to the applied force the additional stretching is δ

∴ F δ + mgδ = 2 1 K K g m K mg 2 2 2 2 −       _+δ = 2 1 K K g m K mg K g m 2 2 2 2 2 2 2 2 −     _{+δ +} δ = 2 1 K δ2 _{+ mgδ ⇒ δ =} K F 2 . Example : 09

A stone is projected at time t = 0 with a speed V0 and an angle θ with the horizontal in a

uniform gravitational field. The rate of work done (P) by the gravitational force plotted against time (t) will be as

A) B) C) D)

Solution :

Rate of work done is the power associated with the force. It means rate of work done by the gravitational force is the power associated with the gravitational force. Gravitational force acting on the block is equal to its weight mg which acts vertically downwards.

Velocity of the particle (at time t) has two components,

(i) a horizontal component v cosθ and

P

O

t

P

O

t

P

O

t

O

t

P

(ii) a vertically upward component (v sinθ - gt)

Hence, the power associated with her weight mg will be equal to p = m→_g .→_v = -mg (v

sinθ - gt)

This shows that the curve between power & time will be straight line having positive slope but negative intercept on Y-axis.

IIT- P-WPE

15

SINGLE ANSWER TYRE

.

LEVEL - I .

1. Two springs A and B(KA = 2KB) are stretched by applying forces of equal magnitudes at

the four ends. If the energy stored in A is E, that in B is

a) E/2 b) 2E c) E d) E/4

2. Two equal masses are attached to the two ends of a spring constant K. The masses are

pulled out symmetrically to stretch the spring by a length x over its natural length. The work done by the spring on each mass is

a) ½ Kx2 _{b) -1/2 Kx}2 _{c) ¼ Kx}2 _{d) -1/4 Kx}2

3. The negative of the work done by the conservative internal forces on a system equals

the change in

a) total energy b) kinetic energy c) potential energy d) none of these

4. The work done by the external forces on a system equals the change in

a) total energy b) kinetic energy c) potential energy d) none of these

5. The work done by all the forces (external and internal) on a system equals the change in

a) total energy b) kinetic energy c) potential energy d) none of these

6. ________ of a two particle system depends only on the separation between the two

particles. The most appropriate choice for the blank space in the above sentence is

a) kinetic energy b) total mechanical energy

c) potential energy d) total energy

7. A small block of mass ‘m’ is kept on a rough inclined surface of inclination θ fixed in an

elevator. The elevator goes up with a uniform velocity ‘v’ and the block does not slide on the wedge. The work done by the force of friction on the block in time ‘t’ will be

a) zero b) mgvt cos2_{θ c) mgvt sin}2_{θ d) mgvt sin2θ}

8. A block of mass ‘m’ slides down a smooth vertical circular track. During the motion, the

block is in

a) vertical equilibrium b) horizontal equilibrium

c) radial equilibrium d) none of these

9. A particle is rotated in a vertical circle by connecting it to a string of length ‘l’ and

keeping the other end of the string fixed. The minimum speed of the particle when the string is horizontal for which the particle will complete the circle is

a) gl b) 2gl c) 3gl d) 5gl

10. Consider two observers moving with respect to each other at a speed v along a straight

line. They observe a block of mass m moving a distance ‘l’ on a rough surface. The following quantities will be same as observed by the two observers

a) kinetic energy of the block at time t b) work done by friction

c) total work done on the block d) acceleration of the block

11. A particle of mass ‘m’ is attached to a light string of length ‘l’, the other end of which is

fixed. Initially the string is kept horizontal and the particle is given an upward velocity v. The particle is just able to complete a circle

a) the string becomes slack when the particle reaches its highest point b) the velocity of the particle becomes zero at the highest point

c) the kinetic energy of the ball in initial position was ½ mv2 _{= mgl}

d) the particle again passes through the initial position

12. The kinetic energy of a particle continuously increases with time

a) the resultant force on the particle must be parallel to the velocity at all instants

b) the resultant force on the particle must be at an angle less than 900 _{all the time}

c) its height above the ground level must continuously decrease d) the magnitude of its linear momentum is increasing continuously

13. One end of a light spring of spring constant k is fixed to a wall and the other end is tied

to a block placed on a smooth horizontal surface. In a displacement, the work done by

the spring is ½ kx2_{. The possible cases are}

a) the spring was initially compressed by a distance x and was finally in its natural length

b) it was initially stretched by a distance x and finally was in its natural length c) it was initially in its natural length and finally in a compressed position d) it was initially in its natural length and finally in a stretched position

14. A block of mass ‘M’ is hanging over a smooth and light pulley through a light string. The

other end of the string is pulled by a constant force F. The kinetic energy of the block increases by 20J in 1s

a) the tension in the string is Mg b) the tension in the string is F

c) the work done by the tension on the block is 20J in the above is 1s d) the work done by the force of gravity is –20J in the above 1s

15. A particle of mass 0.25kg moves under the influence of a force F = (2x-1). If the velocity

of the particle at x = 0 is 4m/s. its velocity at x = 2m will be

A) 4 2 m/s B) 2 2 m/s C) 8m/s D) 6m/s

16. Work done to accelerate a car from 10 to 20m/s compared with that required to

accelerate it from 0 to 10m/s is

A) twice B) three times C) four times D) same

17. Two springs have their force constant as K1 and K2 (K1 > K2). When they are stretched by

the same force :

A) no work is done in case of both the springs B) equal work is done in case of both

the springs

C) more work is done in case of second spring D) more work is done in case of first

spring

18. The kinetic energy K of a particle moving in a straight line depends upon the distance s

as K = as2 _{where a is a constant. The force acting on the particle is}

A) 2as B) 2mas C) 2a D) _as2

19. A particle moves in a straight line with a retardation proportional to its displacement. Its

loss of kinetic energy for any displacement x is proportional to

A) x B) x2 _{C) ln x D) e}x

IIT- P-WPE

17

A) If conservative forces are doing negative work then potential energy will increase and kinetic energy will decrease.

B) If kinetic energy is constant it means work done by conservative forces is zero.

C) for change in potential energy only conservative forces are responsible, but for change in kinetic energy other than conservative forces are responsible

D) all of the above are wrong

21. Instantaneous power of a constant force acting on a particle moving in a straight line

under the action of this force :

A) is constant B) increases linearly with time

C) decreases linearly with time D) either increases or decreases linearly with

time.

22. Suppose y represents the work done and x the power, then dimensions of

2 2 dx y d will be : A)

_



M L T

−1 −2 4



_

B)

_



M L T

2 −3 −2

_



C)



_

M L T

−2 −4 −4



_

D)

_



ML T

3 −6



_

23. Choose the correct statement Work done by a variable force

A) Is defined as F .Suur ur B) Is independent of path

C) Is always dependent on the initial and final positions D) None of these

24. Identify the correct statement for a non-conservative force

A) A force which is not conservative is called a non-conservative force B) The work done by this force depends on the path followed

C) The word done by this force along a closed path is zero D) The work done by this force is always negative

25. The figure shows a plot of potential energy function, u(x) = kx2

where x is the displacement and k is a constant. Identify the correct conservative force function F(x)

26. A plot of velocity versus time is shown in figure. A single force acts on the body. Find

correct statement

A) In moving from C to D, work done by the force on the body is positive B) In moving from B to C, work done by the force on the body is positive C) In moving from A to B, the body does work on the system and is negative

D) In moving from O to A, work done by the body and is negative

LEVEL - II .

1. A particle of mass m is moving in a circular path of radius r under the influence of

centripetal force F = C/r2_{. The total energy of the particle is}

a) r 2 C − b) r 2 C _{c) C x 2r d) Zero}

2. Water from a stream is falling on the blades of a turbine at the rate of 100kg/sec. If the

height of the stream is 100m then the power delivered to the turbine is

a) 100 kw b) 100 w c) 10 kw d) 1 kw

3. A body is being moved along a straight line by a machine delivering a constant power.

The distance covered by the body in time t is proportional to

a) 1 b) t3/2 c) t3/4 d) t2

4. A ball is dropped from a height of 10m. If 40% of its energy is lost on collision with the

earth then after collision the ball will rebound to a height of

a) 10m b) 8m c) 4m d) 6m

5. A particle moves under the influence of a force F = CX from X = 0 to X = X1. The work

done in this process will be a) 2 CX₁2 _b) 2 1 CX c) 3 1 CX d) 0

6. A uniform chain of mass M and length L lies on a horizontal table such that one third of

its length hangs from the edge of the table. The work done is pulling the hanging part on the table will be

a) 3 MgL b) MgL c) 9 MgL d) 18 MgL

7. An electric motor produces a tension of 4500N in a load lifting cable and rolls it at the

rate of 2m/s. The power of the motor is

a) 9 kw b) 15 kw c) 225 kw d) 9 x 103 _HP

8. The relation between time and displacement of a particle moving under the influence of

a force F is t = x+3 where x is in meter and t in second. The displacement of the

particle when its velocity is zero will be

a) 1 m b) 0 m c) 3 m d) 2 m

9. A moving particle of mass m collides head on with another stationary particle of mass

2m. What fraction of its initial kinetic energy will m lose after the collision?

a) 9/8 b) 8/9 c) 19/18 d) 18/19

10. Two particles each of mass m and traveling with velocities u1 and u2 collide perfectly

inelastically. The loss of energy will be

a) ½ m(u1 – u2)2 b) ¼ m(u1 – u2)2 c) m(u1 – u2)2 d) 2m(u1

– u2)2

11. A liquid in a U tube is changed from position (a) to position

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19

area of cross section of the tube is a. The work done in pumping the liquid will be

a) dgha b) dgh2_a

c) 2gdh2_{a d) 4dgh}2_a

12. A man pulls a bucket full of water from a h metre deep well. If the mass of the rope is m

and mass of bucket full of water is M, then the work done by the man is

a) m gh 2 M     _{+ b) gh} 2 m M     + _{c) gh} 2 m M     + d) (M + m) gh

13. The force-displacement curve for a body moving on a smooth

surface under the influence of force F acting along the direction of displacement s has been shown in fig. If the initial kinetic energy of the body is 2.5J. its kinetic energy at s = 6m is

A) 7J B) 4.5J C) 2.25J

D) 9J

14. A bullet, moving with a speed of 150m/s, strikes a wooden plank. After passing through

the plank its speed becomes 125m/s. Another bullet of the same mass and size strikes the plank with a speed of 90m/s. It speed after passing through the plank would be

A) 25m/s B) 35m/s C) 50m/s D) 70m/s

15. A man of mass 60kg climbs a staircase inclined at 450 _{and having 10steps. Each step is}

20cm high. He takes 2 seconds for the first five steps and 3 seconds for the remaining five steps. The average power of the man is

A) 245W B) 245 2 W C) 235 2 W D) 235W

16. The potential energy of a particle moving in x-y plane is given by U = x2 _{+ 2y. The force}

acting on the particle at (2, 1) is

A) 6N B) 20N C) 12N D) 0

17. Water is flowing in a river at 20m/s. The river is 50m wide and has an average depth of

5m. The power available from the current in the river is

A) 0.5MW B) 1.0MW C) 1.5MW D) 2.0MW

18. A 5kg brick of dimensions 20cm x 10cm x 8cm is lying on the largest base. It is now

made to stand with length vertical. If g = 10m/s2_{, then the amount of work done is}

A) 3J B) 5J C) 7J D) 9J

19. A body of mass m was slowly pulled up the hill by a force F which

at each point was directed along the tangent of the trajectory. All surfaces are smooth. Find the work performed by this force

A) mg B) -mg

C) mgh D) zero

20. A rope ladder with a length l carrying a man of mass m at its end, is attached to the

basket of a balloon of mass M. The entire system is in equilibrium in air. As the man climbs up the ladder into the balloon, the balloon descends by height h. Then the potential energy of man

C) increases by mgh D) increases by mg (2 l -h)

21. Two springs s1 and s2 have negligible masses and the spring constant of s1 is

one-third that of s2. When a block is hung from the springs as shown, the

springs came to the equilibrium again. The ratio of work done is stretching s1 to

s2 is

A) 1/9 B) 1/3 C) 1 D) 3

22. A light spring of length l and spring constant 'k' it is placed vertically. A small ball of

mass m falls from a height h as measured from the bottom of the spring. The ball attaining to maximum velocity when the height of the ball from the bottom of the spring is

A) mg/k B) l-mg/k C) l + mg/k D) l - k/mg

23. A block of mass 1kg is permanently attached with a spring of spring constant k =

100N/m. The spring is compressed 0.20m and placed on a horizontal smooth surface. When the block is released, it moves to a point 0.4m beyond the point when the spring is at its natural length. The work done by the spring in changing from compressed state to the stretched state is

A) 10J B) -6J C) -8J D) 18J

24. A chain of length l and mass m lies on the surface of a smooth sphere of radius R with

one end tied on the top of the sphere. If  = πR/2, then the potential energy of the

chain with reference level at the centre of sphere is give by

A) m R g B) 2m R g C) 2/π m R g D) 1/π m R g

25. _{If the force acting on a particle is given by F = 2i + xyj + xz}2_{k, how much work is done}

when the particle moves parallel to Z-axis from the point (2, 3, 1) to (2, 3, 4) ?

A) 42J B) 48J C) 84J D) 36J

26. A uniform chain of length '' and mass m is placed on a smooth table with one-fourth

of its length hanging over the edge. The work that has to be done to pull the whole chain back onto the table is

A) 4 1 mgl B) 8 1 mgl C) 16 1 mgl D) 32 1 mgl

27. A spring, which is initially in its unstretched condition, is first stretched by a length x and

then again by a further length x. The work done in the first case is W1 and in the second

case is W2

A) W2 = W1 B) W2 = 2W1 C) W2 = 3W1 D) W2 = 4W1

28. A particle of mass m is fixed to one end of a light rigid rod of length '' and rotated in a

vertical circular path about its other end. The minimum speed of the particle at its highest point must be

IIT- P-WPE

21

29. A particle is moving in a conservative force field from point A to B. UA and UB are the

potential energies of the particle at points A and B and Wc is the work done in the

process of taking the particle from A to B.

A) Wc = UB - UA B) Wc = UA - UB C) UA > UB D) UB >

UA

30. A force is given by Mv2_{/r when the mass moves with speed v in a circle of radius r. The}

work done by this force in moving the body over upper half circle along the circumference is

A) zero B) ∞ C) Mv2 _{D) Mv}2_π/2

31. A moving railway compartment has a spring of constant 'k' fixed to its front wall. A boy

in the compartment stretches this spring by distance x and in the mean time the compartment moves by a distance s. The work done by boy w.r.t earth is

A) kx2 2 1 B) 2 1 (kx) (s+x) C) kxs 2 1 D) kx

(

s x s

)

2 1 + +

32. Force acting on a block moving along x-axis is given by : F = N

2 x 4 2     + − The block is displaced from x=-2m to x=+4m, the work done will be

A) positive B) negative

C) zero D) may be positive or negative

33. The system is released from rest with both the springs in unstretched positions. Mass of

each block is 1 kg and force constant of each springs is 10 N/m. Extension of horizontal spring in equilibrium is:

A) 0.2m B) 0.4m C) 0.6m D)

0.8m

34. In a projectile motion, if we plot a graph between power of the force acting on the

projectile and time then it would be like :

A) B) C) D)

35. A golfer rolls a small ball with speed u along the floor from point

A. If x = 3R, determine the required speed u so that the ball returns to A after rolling on the circular surface in the vertical plane from B to C and becoming a projectile at C. (Neglect friction) A) gR 5 2 B) gR 2 5 C) gR 7 5 D) none of these LEVEL - III .

1. A block m is pulled by applying a force F as shown in fig. If the block has moved up through a distance 'h', the work done by the force F is

A) 0 2) Fh C) 2Fh D)

2 1

Fh

2. A body of mass m, having momentum p is moving on a rough horizontal surface. If it is

stopped in a distance x, the coefficient of friction between the body and the surface is given by

A) µ = p/(2mg x) B) µ = p2 _{/ (2mg s) C) µ = p}2 _{/ (2g m}2_{s) D) µ = p}2 _{(2g m}2_s2₎

3. A body of mass m moves from rest, along a straight line, by an engine delivering

constant power P. the velocity of the body after time t will be A) m Pt 2 _B) m Pt 2 _C) m 2 Pt _D) m 2 Pt

4. The spring shown in fig has a force constant k and the mass of block is m.

Initially, the spring is unstretched when the block is released. The maximum elongation of the spring on the releasing the mass will be

A) k mg B) 2 1 k mg C) 2 k mg D) 4 k mg

5. A skier starts from rest at point A and slides down the hill,

without turning or braking. The friction coefficient is µ. When he

stops at point B, his horizontal displacement is S. The height difference h between points A and B is

A) h = S/µ B) h = µS

C) h = µS2 _{D) h = S/µ}2

6. A block of mass m starts at rest at height h on a frictionless

inclined plane. The block slides down the plane travels a total distance d across a rough horizontal surface with

coefficient of kinetic friction µk and compresses a spring

with force constant k, a distance x before momentarily

coming to rest. The spring then extends and the block travels back across the rough surface, sliding up the plane. The maximum height h' that the block reaches on its return is A) h' = h - 2µd B) h' = h - 2µd - 2 1 kx2 _{C) h' = h - 2µd + kx}2 _{D) h' = h} - 2µd - kx2

7. A chain of length 3 and mass m lies at the top of smooth prism

such that its length  is one side and 2 is on the other side of

IIT- P-WPE

23

move. If the chain is released. What will be its velocity when the right end of the chain is just crossing the top-most point?

A) 2gl B) gl 3 2 _{C) l} g 3 1 _{D) l} g 2 1

8. If a constant power P is applied in a vehicle, then its acceleration increases with time

according to the relation

A) a = t m 2 P         B) a = t3/2 m 2 P         C) a = 1/t m 2 P         D) a = mt 2 P

9. A body of mass m slides downward along a plane inclined at an angle α. The coefficient

of friction is µ. The rate at which kinetic energy plus gravitational potential energy

dissipates expressed as a function of time is

A) µmtg2 _{cos α B) µmtg}2 _{cos α (sin α - µ cos α)}

C) µmtg2 _{sin α D) µmtg}2 _{sin α (sin α - µ cos α)}

10. The potential energy for a force field F is given by U(x, y) = sin (x + y). The force

acting on the particle of mass m at (0, π/4) is

A) 1 B) 2 C) 1/ 2 D) 0

11. A uniform rope of length '' and mass m hangs over a horizontal table with two third

part on the table. The coefficient of friction between the table and the chain is µ. The

work done by the friction during the period the chain slips completely off the table is

A) 2/9 µmgl B) 2/3 µmgl C) 1/3 µmgl D) 1/9 µmgl

12. A particle is moving in a force field given by potential U = - λ(x + y + z) from the point

(1, 1, 1) to (2, 3, 4). The work done in the process is

A) 3λ B) 1.5λ C) 6λ D) 12λ

13. A compressed spring of spring constant k releases a ball of mass

m. If the height of spring is h and the spring is compressed through a distance x, the horizontal distance covered by ball to reach ground is A) x mg kh B) mg xkh C) x mg kh 2 D) kh x mg

14. A block of mass m = 2kg is moving with velocity vo towards

a massless unstretched spring of force constant K = 10 N/m. Coefficient of friction between the block and the

ground is µ = 1/5. Find maximum value of vo so that after

pressing the spring the block does not return back but stops there permanently.

15. Potential energy of a particle moving along x-axis under the action of only conservative

forces is given as : U = 10 + 4 sin(4πx). Here U is in Joule and x in meters. Total

mechanical energy of the particle is 16J. Choose the correct option.

A) At x = 1.25m, particle is at equilibrium position. C) both A and B are correct

B) Maximum kinetic energy of the particle is 20J D) both A and B are wrong.

16. A system shown in figure is released from rest. Pulley and spring is

massless and friction is absent everywhere. The speed of 5 kg block when 2 kg block leaves the contact with ground is (Take force constant of spring

k = 40 N/m and g = 10 m/s2₎

A) 2 m/s` B) 2 2 m/s

C) 2m/s D) 4 2 m/s

17. Two blocks of masses m1 = 1 kg and m2 = 2 kg are connected

by a non-deformed light spring. They are lying on a rough horizontal surface. The coefficient of friction between the

blocks and the surface is 0.4 what minimum constant force F has to be applied in

horizontal direction to the block of mass m1 in order to shift the other block? (g = 10

m/s2₎

A) 8 N B) 15 N C) 10 N D) 25 N

18. A block of mass m is attached with a massless spring of force

constant k. The block is placed over a rough inclined surface for

which the coefficient of friction is µ = ¾. The minimum value of M

required to move the block up the plane is (Neglect mass of string and pulley and friction in pulley).

A) 3/5m B) 4/5m C) 6/5m D) 3/2m

MULTIPLE ANSWER TYPE QUESTIONS

.

1. _{The potential energy U for a force field F} is such that U = - kxy, where k is a constant

A) F=kyiˆ+kxˆj B) F=kxiˆ+kyˆj

C) The force F is a conservative force _{D) The force F} is a non-conservative

force

2. Two blocks A and B each of mass m are connected by

a light spring of natural length L and spring constant k. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length, as shown. A

third identical block C, also of mass m, moves on the floor with a speed v along the line joining A to B and collides with A. Then

A) the kinetic energy of the A-B system at maximum compression of the spring is zero B) the kinetic energy of the A-B system at maximum compression of the spring is

IIT- P-WPE 25         4 mv2

C) the maximum compression of the spring is _

      k m v

D) the maximum compression of the spring is _

      k 2 m v

3. The kinetic energy of a body moving along a straight line varies directly with time t. If

the velocity of the body is v at time t, then the force F acting on the body is such that

A) F ∝ t1/2 _{B) F ∝ t}-1/2 _{C) F ∝ v D) F ∝ v}-1

4. A car of mass m is moving on a level road at a constant speed vmax while facing a

resistive force R. If the car slows down to vmax/3, then assuming the engine to be

working at the same power, what force F is developing and what is the acceleration a of the car ?

A) F = 3R B) F = 2R C) a = 3P/m vmax D) a = 2 P/m vmax

5. The potential energy of a particle of mass 1 kg moving in xy plane is given by U = 10 -

4x - 3y

The particle is at rest at (2, 1) at t = 0. Then

A) velocity of particle at t = 1 is 5 m/s B) the particle is at (10m, 7m) at t =

2s

C) work done during t = 1s to t = 2s is 75J D) the magnitude of force acting on particle is 5N

6. A block of mass m is gently placed on a vertical spring of stiffness k. Choose the correct

statement related to the mechanical energy E of the system.

A) It remains constant B) It decreases C) It increases D)

Nothing can be said

7. A spring of stiffness k is pulled by two forces FA and FB as shown in

the figure so that the spring remains in equilibrium. Identify the correct statement (s) :

A) The work done by each force contributes into the increase in potential energy of the spring

B) The force undergoing larger displacement does positive work and the force undergoing smaller displacement does negative work

C) Both the forces perform positive work

D) The net work done is equal to the increase in potential energy

8. A particle of mass m is released from a height H on a smooth curved

surface which ends into a vertical loop of radius R, as shown in figure.

If θ is the instantaneous angle which the line joining the particle and

the centre of the loop makes with the vertical, the identify the

A) The maximum value N occurs at θ = 0 B) The minimum value of N occurs at N = π

C) The value of N becomes negative for π/2 < θ <

2 3π

D) The value of N becomes zero only when θ > π/2

9. An engine is pulling a train of mass m on a level track at a uniform speed v. The

resistive force offered per unit mass is f A) Power produced by the engine is mfv

B) The extra power developed by the engine to maintain a speed v up a gradient of h in s is

s mghv

C) The frictional force exerting on the train is mf on the level track D) None of above is correct

10. A particle of mass 5 kg moving in the x-y plane has its potential energy given by U =

(-7x + 24y) J, where x and y are in metre. The particle is initially at origin and has a velocity _u_{=(14.4iˆ+4.2}ˆ_j)ms−1

A) The particle has a speed of 25 ms-1 _{at t = 4 s B) The particle has an acceleration of}

5 ms-2

C) The acceleration of the particle is perpendicular to its initial velocity D) None of the above is correct

* * * * *

MULTIPLE MATCHING TYPE QUESTIONS :

.

1.

List - I List - II

a) Area under F - S e) Change in KE

b) Work energy theorem f) negative of work done to gravitational

force

c) change in PE g) work done by F

d) conservative force _{h) −}

_∫

_F_{.dx, where F is conservative}

force

i) gravitational force 2.

IIT- P-WPE

27

List - I List - II

a) KE e) depends on frame of reference

b) work done f) defined for conservative force only

c) PE g) independent on frame of reference

d) spring PE h) same for either compression or

elongation for same distance 3.

List - I List - II

a) stable equilibrium e) PE in Max

b) unstable equilibrium f) Fnet = 0

c) 0 dx dF ≤ g) PE is Min d) 0 dx dF

≥ h) slope of F-x graph is +ve

4.

List - I List - II

a) work done by frictional force e) indepent of path

b) work done by electrostatic force f) non-conservative

c) work done by gravitational force for closed loop

g) depends on path

d) for slowly moving body, wc + wn.c

equal to

h) define PE i) zero

* * * * *

ASSERTION AND REASON :

.

Read the assertion and reason carefully to mark the correct option out of the options given below:

(a) If both assertion and reason are true and the reason is the correct explanation of the assertion.

(b) If both assertion and reason are true but reason is not the correct explanation of the assertion.

(c) If assertion is true but reason is false. (d) If assertion is false but reason is true.

1. Assertion : A person working on a horizontal road with a load on his head does no

work.

Reason : No work is said to be done, if directions of force and displacement of

2. Assertion : Work done by friction on a body sliding down an inclined plane is positive. Reason : Work done is greater than zero, if angle between force and displacement

is acute or both are in same direction.

3. Assertion : When a gas is allowed to expand, work done by gas is positive.

Reason : Force due to gaseous pressure and displacement (of piston) are in the

same direction.

4. Assertion : The instantaneous power of an agent is measured as the dot product of

instantaneous velocity and the force acting on it at that instant.

Reason : The unit of instantaneous power is watt.

5. Assertion : The change in kinetic energy of a particle is equal to the work done on it by

the net force.

Reason : Change in kinetic energy of particle is equal to the work done only in

case of a system of one particle.

6. Assertion : A spring has potential energy, both when it is compressed or stretched. Reason : In compressing or stretching, work is done on the spring against the restoring

force.

7. Assertion : Comets move around the sun in elliptical orbits. The gravitational force on

the comet due to sun is not normal to the comet’s velocity but the work done by the gravitational force over every complete orbit of the comet is zero.

Reason : Gravitational force is a non conservative force.

8. Assertion : The rate of change of total momentum of a many particle system is

proportional to the sum of the internal forces of the system.

Reason : Internal forces can change the kinetic energy but not the momentum of the

system.

9. Assertion : Water at the foot of the water fall is always at different temperature from

that at the top.

Reason : The potential energy of water at the top is converted into heat energy

during falling.

10. Assertion : The power of a pump which raises 100 kg of water in 10sec to a height of

100 m is 10 KW.

Reason : The practical unit of power is horse power.

11. Assertion : According to law of conservation of mechanical energy change in potential

energy is equal and opposite to the change in kinetic energy.

Reason : Mechanical energy is not a conserved quantity.

12. Assertion : When the force retards the motion of a body, the work done is zero. Reason : Work done depends on angle between force and displacement.

13. Assertion : Power developed in circular motion is always zero. Reason : Work done in case of circular motion is zero.

14. Assertion : A kinetic energy of a body is quadrupled, when its velocity is doubled. Reason : Kinetic energy is proportional to square of velocity.

15. Assertion : Work done by or against gravitational force in moving a body from one

IIT- P-WPE

29

Reason : Gravitational forces are conservative forces.

16. Assertion : Graph between potential energy of a spring versus the extension or

compression of the spring is a straight line.

Reason : Potential energy of a stretched or compressed spring, proportional to square

of extension or compression.

17. Assertion : Heavy water is used as moderator in nuclear reactor. Reason : Water cool down the fast neutron.

18. Assertion : If two protons are brought near one another, the potential energy of the

system will increase.

Reason : The charge on the proton is _+1.6×10−19C_.

19. Assertion : In case of bullet fired from gun, the ratio of kinetic energy of gun and bullet

is equal to ratio of mass of bullet and gun.

Reason : In firing, momentum is conserved.

20. Assertion : Power of machine gun is determined by both, the number of bullet fired per

second and kinetic energy of bullets.

Reason : Power of any machine is defined as work done (by it) per unit time.

21. Assertion : Mountain roads rarely go straight up the slope.

Reason : Slope of mountains are large therefore more chances of vehicle to slip

from roads.

* * * * *

IIT TRACK QUESTIONS : .

1. A ball hits the floor and rebounds after inelastic collision. In this case [IIT 1986]

(a) The momentum of the ball just after the collision is the same as that just before the collision

(b) The mechanical energy of the ball remains the same in the collision (c) The total momentum of the ball and the earth is conserved

(d) The total energy of the ball and the earth is conserved

length is hanging vertically down over the edge of the table. If g is acceleration due to gravity, the work required to pull the hanging part on to the table is [IIT 1985]

(a) MgL (b) MgL/3 (c) MgL/9 (d) MgL/18

3. A particle of mass m is moving in a horizontal circle of radius r under a centripetal force

equal to _{−K / r}2_{, where K is a constant. The total energy of the particle is [IIT}

1977] (a) r K 2 (b) r K 2 − (c) r K − (d) r K

4. The displacement x of a particle moving in one dimension under the action of a constant

force is related to the time t by the equationt= x+3, where x is in meters and t is in

seconds. The work done by the force in the first 6 seconds is [IIT 1979]

(a) 9 J (b) 6 J (c) 0 J (d) 3 J

5. A force F=−K(yi+xj) (where K is a positive constant) acts on a particle moving in

the xy-plane. Starting from the origin, the particle is taken along the positive x-axis to the point (a, 0) and then parallel to the y-axis to the point (a, a). The total work done by the force F on the particles is [IIT 1998]

(a) _−2Ka2 _{(b) 2Ka}2 _{(c) −Ka}2 _{(d) Ka}2

6. If g is the acceleration due to gravity on the earth's surface, the gain in the potential

energy of an object of mass m raised from the surface of earth to a height equal to the radius of the earth R, is

[IIT 1983] (a) mgR 2 1 (b) 2 mgR (c) mgR (d) mgR 4 1

7. A lorry and a car moving with the same K.E. are brought to rest by applying the same

retarding force, then [IIT 1973]

(a) Lorry will come to rest in a shorter distance (b) Car will come to rest in a shorter

distance

(c) Both come to rest in a same distance (d) None of the above

8. A particle free to move along the x-axis has potential energy given by

] ) exp( 1 [ ) (_{x k x}2

U = − − for

−∞

≤

x

≤

+∞

, where k is a positive constant of appropriate

dimensions. Then [IIT-JEE 1999]

(a) At point away from the origin, the particle is in unstable equilibrium

(b) For any finite non-zero value of x, there is a force directed away from the origin (c) If its total mechanical energy is k/2, it has its minimum kinetic energy at the origin (d) For small displacements from x = 0, the motion is simple harmonic

9. A body is moved along a straight line by a machine delivering constant power. The

distance moved by the body in time t is proportional to [IIT 1984]

IIT- P-WPE 31 2 t

10. A shell is fired from a cannon with velocity v m/sec at an angle θ with the horizontal

direction. At the highest point in its path it explodes into two pieces of equal mass. One of the pieces retraces its path to the cannon and the speed in m/sec of the other piece immediately after the explosion is [IIT 1984]

(a) 3vcosθ (b) 2vcosθ (c) cosθ

2 3_v (d) cosθ 2 3 v

11. Two particles of masses m and 1 m in projectile motion have velocities 2 v1



and v2



respectively at time t = 0. They collide at time t . Their velocities become 0 v1'



and

' 2

v at time 2t 0 while still moving in air. The value of

) ( ) ' ' ( | m1v1 +m2v2 −m1v1+m2v2 | is [IIT-JEE Screening 2001] (a) Zero (b) (m1+m2)gt0 (c) 2(m1+m2)gt0 (d) 0 2 1 ) ( 2 1 gt m m +

12. A particle is placed at the origin and a force F =kxis acting on it (where k is positive

constant). If U(0)=0, the graph of U(x) versus x will be (where U is the potential

energy function) [IIT-JEE (Screening) 2004]

(a) (b) (c) (d)

* * * * *

x U(x) x U(x) x U(x) x U(x)

SINGLE ANSWER TYRE

.

LEVEL - I . 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 B D C A B C C D C D AD BD AB B A 16 17 18 19 20 21 22 23 24 25 26 B C A B D B A C B B A LEVEL - II . 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 A A B D A D A B B B B C A B D 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 B B A C B D B B C A D C A B A 31 32 33 34 35 A B B B B LEVEL - III . 1 2 3 4 5 6 7 8 9 10 11 C C A C B A B D B A A 12 13 14 15 16 17 18 C C D A B A A

MULTIPLE ANSWER TYPE QUESTIONS .

1 2 3 4 5 6 7 8 9 10

AC BD BD AD ABD B ACD ABD ABC ABC

MULTIPLE MATCHING TYPE QUESTIONS .

1 2 3 4

a-eg, b-e, c-fh, d-i a-e, b-e, c-ef, d-gh a-fg, b-efh, c-g, d-eh a-fg, b-eh, c-i, d-i

ASSERTION AND REASON .

1 2 3 4 5 6 7 8 9 10 11

A D A B C A C D A B C

12 13 14 15 16 17 18 19 20 21

D D A A D C B A A A

IIT TRACK QUESTIONS : .

1 2 3 4 5 6 7 8 9 10 11 12