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Objective questions, contained in this module with hidden solutions, help improve understanding of the topics covered under the module "Conservation of angular momentum".

The questions have been selected to enhance understanding of the topics covered in the module titled " Conservation of angular momentum ". All questions are multiple choice questions with one or more correct answers. There are two sets of the questions. The “understanding level” questions seek to unravel the fundamental concepts involved, whereas “application level” are relatively difficult, which may interlink concepts from other topics.

Each of the questions is provided with solution. However, it is recommended that solutions may be seen only when your answers do not match with the ones given at the end of this module.

Understanding level (conservation of angular momentum)

If the polar ice caps completely melt due to warming, then :

(a) the earth will rotate faster (b) the earth will rotate slower (c) there will be no change in the angular speed (d) duration of a day on the Earth will increase

The gravitational pull of the Sun passes through COM of the Earth, providing centripetal force required for the rotation of the Earth about it. Thus, there is no external torque on the Earth. It means that the angular momentum of the Earth remains constant.

The melting of ice cap will result in the rise of sea level. From the point of view of MI of the Earth, it means redistribution of mass. The water equivalent of ice moves away from the axis of rotation, which passes through the poles. This results in an increase in the MI of the Earth.

Now, applying law of conservation of angular momentum :

L i = L f I i ω i = I f ω f

ω f = I i ω i I f

Hence, increase in the MI of the Earth, due to melting of ice, will decrease angular velocity. On the other hand, the duration of a day on the Earth is equal to its time period of rotation, which is given as :

T = 2 π ω f

As the Earth rotate slowly (lesser angular speed, ω f ), the duration of a day on the Earth will increase.

Hence, options (b) and (d) are correct.

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A circular disk of mass “M” and radius “R” is rotating with angular velocity “ω” about its vertical axis. When two small objects each of mass “m” are gently placed on the rim of the disk, the angular velocity of the ring becomes :

(a) M ω ( M + 4 m ) (b) M ω ( M + 2 m ) (c) M ω ( M 2 + 4 m ) (d) Mm ω ( M + 4 m )

Since no external torque is operating on the disk – objects system, the angular momentum of the system is conserved.

Let “ ω f ” be the common angular velocity of the composite system after objects are placed on the disk. Let subscripts “D”, “O” and “C” represent disk, objects and composite system respectively , then according to conservation of angular momentum,

I Di ω Di + I Oi ω Oi = I Ci ω f

Here,

I Di = M R 2 2 ; ω Di = ω ; I Oi = 0 ; ω Oi = 0

Also, the MI of the composite system is :

I Cf = ( M R 2 2 + 2 m R 2 ) = ( M 2 + 2 m ) R 2

Putting in the equation of conservation law,

M R 2 ω 2 = ( M 2 + 2 m ) R 2 ω f

ω f = M ω 2 ( M 2 + 2 m ) = M ω ( M + 4 m )

Hence, options (a) is correct.

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What would be the duration of day, if earth shrinks to half its radius with two – third of its original mass ? Consider motion of the Earth about the Sun along a circular path.

(a) 2 hrs (b) 4 hrs (c) 8 hrs (d) 16 hrs

The Earth rotates around the Sun as gravitational pull provides the necessary centripetal force. This force passes through the center of mass of the Earth. As such, gravitational pull does not constitute torque on the Earth. Therefore, we can consider that angular momentum of the Earth remains unchanged. Now, let us use "i" and "f" subscripts to denote initial and final values, then according to law of conservation of angular momentum :

L i = L f I i ω i = I f ω f

ω f = I i ω i I f

We know that time period of the Earth is :

T i = 24 hrs

Hence, its angular velocity is :

ω i = 2 π T i = 2 π 24 = π 12 rad / s

Since data on mass and radius are missing, it is not possible to calculate MIs in two cases separately. However, we can find the ratio of MIs :

I i I f = 2 M R 2 5 2 5 x 2 M 3 x ( R 2 ) 2 = 1 x 3 x 4 2 = 6

Putting in the equation,

ω f = 6 ω i = 6 x π 12 = π 2 rad / s

The new time period of rotation is :

T f = 2 π ω f = 2 π x 2 π = 4 hrs

Hence, options (b) is correct.

This question underlines the fact that centripetal force does not constitute a torque for rotating body. Further this question describes a hypothetical situation in which mass of the body itself has changed – not its distribution, resulting in the change of MI and hence angular velocity to conserve angular momentum of the system.

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Source:  OpenStax, Physics for k-12. OpenStax CNX. Sep 07, 2009 Download for free at http://cnx.org/content/col10322/1.175
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