NCERT Solutions Class 11 Physics Chapter 6 Work Energy Power

Answer :
The burning of the casing of a rocket in flight (due to friction) results in the reduction of the mass of the rocket.
 According to the conservation of energy:
Total Energy (T.E.) = Potential Energy (P.E) + Kinetic Energy (K.E)
= mgh + (1/2) mv²
The reduction in the rocket’s mass causes a drop in the total energy. Therefore, the heat energy required for the burning is obtained from the rocket.

• The gravitational force on the comet due to sun is a conservation force. Since the work done by a conservative force over a closed path is always zero (irrespective of the nature of path). Hence the work done by the gravitational force over every complete orbit of the comet is zero.
• When an artificial satellite, orbiting around earth, moves closer to earth, its potential energy decreases because of the reduction in the height.
• Since the total energy of the system remains constant, the reduction in P.E. results in an increase in K.E.
• Hence, the velocity of the satellite increases. However, due to atmospheric friction, the total energy of the satellite decreases by a small amount.
• In second case work done is more.

Case (i):-         
Given:
Mass, m = 15 kg
Displacement, s = 2 m
Work done W = FS cosθ; where θ = angle between force and displacement
=mg cosθ
= (15 x 2 x 9.8 cos90⁰) 
=0   (because cos 90⁰ = 0)
Case (ii)
Given:
Mass, m = 15 kg
Displacement, s = 2 m
Here, the direction of the force applied on the rope and the direction of the displacement of the rope are same.
Therefore, the angle between them, θ = 0°
Work done, W = Fs cosθ
= mgs (because cos 0° = 1)
= (15 × 9.8 × 2)
 = 294 J
Hence, more work is done in the second case.

Question : 6.
Underline the correct alternative:

• When a conservative force does positive work on a body, the potential energy of the body increases/decreases/remains unaltered.
• Work done by a body against friction always results in a loss of its kinetic/potential energy.
• The rate of change of total momentum of a many-particle system is proportional to the external force/sum of the internal forces on the system.
• In an inelastic collision of two bodies, the quantities which do not change after the collision are the total kinetic energy/total linear momentum/total energy of the system of two bodies.

Answer :

• Potential energy of the body decreases. A conservative force does a positive work on a body when it displaces the body in the direction of force.
• As a result, the body advances toward the centre of force. It decreases the separation between the two, thereby decreasing the potential energy of the body.
• There will be loss in the kinetic energy. Work is done against the direction of friction which reduces the velocity of the body.
• External force. Internal forces cannot produce any change in the total momentum of a body.
• Hence, the total momentum of a many- particle system is proportional to the external forces acting on the system.
• Total linear momentum. The total linear momentum always remains conserved whether it is an elastic or inelastic collision.

Question : 7.
State if each of the following statements is true or false. Give reasons for your answer.
(a) In an elastic collision of two bodies, the momentum and energy of each body is conserved.
(b) Total energy of a system is always conserved, no matter what internal and external forces on the body are present.
(c) Work done in the motion of a body over a closed loop is zero for every force in nature.
(d) In an inelastic collision, the final kinetic energy is always less than the initial kinetic energy of the system.

Answer :

1. The total momentum and total energy of the system is conserved bot not of each body.
2. The external forces on the system can either increase or decrease the total energy of the system.
3. Work done in the motion of a body over a closed loop is 0 only when the body moves under the action of conservative force.
4. It is not 0 when the forces are non-conservative e.g. frictional forces.
5. In an inelastic collision, the final kinetic energy is always less than the initial kinetic energy of the system. This is because in such collisions, there is always a loss of energy in the form of heat, sound, etc.

Question : 8.
Answer carefully, with reasons:

• In an elastic collision of two billiard balls, is the total kinetic energy conserved during the short time of collision of the balls (i.e. when they are in contact)?
• Is the total linear momentum conserved during the short time of an elastic collision of two balls?
• What are the answers to (a) and (b) for an inelastic collision?
• If the potential energy of two billiard balls depends only on the separation distance between their centres, is the collision elastic or inelastic? (Note, we are talking here of potential energy corresponding to the force during collision, not gravitational potential energy).

Answer :

• It is because during collision (when the balls are in contact), K.E. of the balls gets converted into potential energy.
• However, K.E. before and after the elastic collision is the same.
• The total linear momentum of the system is always conserved.
• For inelastic collisions for the option (a) it is No. Because in an inelastic collision, there is always loss of kinetic energy.
• The kinetic energy before collision will always be greater than that of after collision.

For option (b) yes. The total linear momentum of the system of billiards balls will remain conserved even in the case of an inelastic collision.

• The collision is elastic. It is because the forces which are involved are conservative.

Question : 9.
A body is initially at rest. It undergoes one-dimensional motion with constant acceleration. The power delivered to it at time t is proportional to
(i) (t) ^1/2 (ii) t  (iii) (t)^3/2 (iv) (t)²

Answer :
Correct option: (ii) t
Given:
Mass of the body = m
Acceleration of the body = a
Using Newton’s second law of motion: F = ma
As both (m) and (a) are constants therefore F is also constant.
F = ma = Constant   (i)
Also acceleration a = (dv/dt) = Constant
Or dv= (Constant x dt)
=>v =at       (ii) where (a) is also constant.
This shows v ∝ t   (iii)
P = F.v
Using equations (i) and (iii), we have:
=> P∝ t
Hence, power is directly proportional to time.

Question : 10.
A body is moving unidirectional under the influence of a source of constant power. Its displacement in time t is proportional to
(i) (t) ^1/2(ii) t (iii) (t) ^3/2 (iv) (t) ²

Answer :
Correct option: (iii)
Let Power = P which is constant.
Initial velocity u =0
Also, P = Fv = mav (using f = ma)
Therefore P = ma²t
=> a = √ (P)/ (mt)
Also we know that s = ut + (1/2) a t²
Thus, s = (1/2) √ (P)/ (mt) t²
=> s = (1/2) √ (P)/ (mt ^(3/2))
So s ∝ mt ^(3/2)

Question : 11.
A body constrained to move along the z-axis of a coordinate system is subject to a constant force F given by F = (-î +2 ĵ +3 k̂) N Where î , ĵ and k̂ 
are unit vectors along the x-, y- and z-axis of the system respectively. What is the work done by this force in moving the body a distance of 4 m along the z-axis?

Answer :
Force exerted on the body, F = (-î +2 ĵ +3 k̂) N
Displacement, s = 4 k̂m
Work done, W = F.s
= (-î +2 ĵ +3 k̂). (4 k̂)
=0+0+3×4
=12J
Hence, 12 J of work is done by the force on the body.

Question : 12.
An electron and a proton are detected in a cosmic ray experiment, the first with kinetic energy 10 keV, and the second with 100 keV.
Which is faster, the electron or the proton? Obtain the ratio of their speeds.
(Electron mass = 9.11 × 10^–31 kg, proton mass = 1.67 × 10^–27 kg,
1 eV = 1.60 × 10^–19 J).

Answer :
Electron is faster; Ratio of speeds is 13.54: 1
Mass of the electron, m_e = 9.11 × 10^–31 kg
Mass of the proton, m_p = 1.67 × 10^{– 27} kg
Kinetic energy of the electron, E_Ke = 10 keV = 10⁴ eV
= 10⁴ × 1.60 × 10^–19
= 1.60 × 10^–15 J
Kinetic energy of the proton, E_Kp = 100 keV = 10⁵ eV = 1.60 × 10^–14 J
For the velocity of an electron v_e, its kinetic energy is given by the relation:
E_ke = (1/2) mv_e²
Therefore, v_e = √ (2 x E_ke)/m
= √ (2 x 1.60 x 10^-15)/ (9.11 x 10^-31)
v_e = (5.93 x 10⁷) m/s
For the velocity of a proton v_p, its kinetic energy is given by the relation:
E_{Kp =} (1/2) mv_p²
Therefore, v_p = √ (2 x E_Kp)/m
v_p = √ (2 x 1.6 x 10^-11)/(1.67 x10^-27)
= (4.38 x 10⁶) m/s
Hence, the electron is moving faster than the proton.
The ratio of their speeds:
(v_e/ v_p) = ((5.93 x 10⁷)/ (4.38 x 10⁶)
=13.54:1

Question : 13.
A rain drop of radius 2 mm falls from a height of 500 m above the ground.
It falls with decreasing acceleration (due to viscous resistance of the air) until at half its original height;
it attains its maximum (terminal) speed, and moves with uniform speed thereafter.
What is the work done by the gravitational force on the drop in the first and second half of its journey?
What is the work done by the resistive force in the entire journey if its speed on reaching the ground is 10 m s^–1?

Answer :
Gravitational force on the rain drop = mg; where m = mass of the rain drop and
 g = acceleration due to gravity which is constant.
As the drop experiences constant gravitational force throughout therefore, work done by the gravitational force on each drop in each half of the journey is same.
Given:
Radius of the rain drop, r =2mm= 2 x10^-3m
Volume of the rain drop, V = (4/3) πr³
= (4/3) x 3.14 x (2 x 10^-3)³ m^-3
Density of water, ρ = 10³ kgm-3
Mass of the rain drop m = ρ V
= (4/3) x 3.14 x (2 x 10^-3)³ x 10³ kg
Gravitational force, F =mg
= (4/3) x 3.14 x (2 x 10^-3)³ x 10³ x 9.8 N
The work done by the gravitational force on the drop in the first half of its journey:
W_I = Fs
= (4/3) x 3.14 x (2 x 10^-3)³ x 10³ x 9.8 x 250
=0.082J
This amount of work is equal to the work done by the gravitational force on the drop in the second half of its journey, i.e., W_II, = 0.082 J
As per the law of conservation of energy, if no resistive force is present, then the total energy of the rain drop will remain the same.
Therefore, total energy at the top:
E_T = mgh + 0
= (4/3) x 3.14 x (2 x 10^-3)³ x 10³ x 9.8 x 500 x 10^-5
= 0.164 J
Due to the presence of a resistive force, the drop hits the ground with a velocity of 10 m/s.
Therefore, total energy at the ground:
E_G = (1/2) mv² +0
= (1/2) x (4/3) x 3.14 x (2 x 10^-3)³ x 10³ x 9.8 x (10)²
=1.675 x 10^-3 J
Therefore resistive force = (E_G – E_T) = -01.62J

Question : 14.
A molecule in a gas container hits a horizontal wall with speed 200 m s^–1 and angle 30° with the normal, and rebounds with the same speed.
Is momentum conserved in the collision? Is the collision elastic or inelastic?

Answer :
Yes, the collision is elastic.
The momentum of gas molecule remains conserved whether collision is elastic or inelastic.
The velocity with which the gas molecule is moving = 200m/s.
When it is striking the stationary wall it is rebounding with the same velocity.
This shows that the rebound velocity of the wall remains 0.Therefore kinetic energy of the molecule remains conserved during the collision.
The given collision is an example of an elastic collision.

Question : 15.
A pump on the ground floor of a building can pump up water to fill a tank of volume 30 m³ in 15 min.
If the tank is 40 m above the ground, and the efficiency of the pump is 30%, how much electric power is consumed by the pump?

Answer :
Given:
Volume of the tank, V = 30 m³
Time, t = 15 min = 15 × 60 = 900 s
Height of the tank, h = 40 m
Efficiency of the pump, η = 30%
Density of water, ρ = 10³ kg/m³
Mass of water, m = (Density x Volume) = ρV = 30 × 10³ kg
Output power can be obtained as:
P_o = (Work done)/ (Time)
= (mgh)/t)
(30 x 10³ x 9.8 x 40)/ (900)
=13.067 x 10³ W
For input power P_i efficiency η is given by the relation:
η = (P_o)/ (P_i)
P_i = (13.067)/ (30) x 100 x 10³
=0.436 x 10⁵ W
P_i = 43.6KW

Question : 16.
Two identical ball bearings in contact with each other and resting on a frictionless table are hit head-on by another ball
bearing of the same mass moving initially with a speed V. If the collision is elastic, which of the following (Fig. 6.14) is a possible result after collision.