Two identical particles each of mass go round a circle due to their mutual gravitational attraction. If the radius of the circular path is , then the angular speed of each particle is
- A
- B
- C
- D
Two identical particles each of mass go round a circle due to their mutual gravitational attraction. If the radius of the circular path is , then the angular speed of each particle is
Correct answer:B
Standard Method
Given: Two identical particles each have mass and each moves in a circular path of radius about the common centre of mass.
Find: The angular speed of each particle.
For equal masses, the common centre of mass lies midway between them, so the separation between the particles is
The gravitational force between the two particles is
This same force provides the centripetal force for each particle. For one particle,
Equating gravitational force and centripetal force,
Cancelling ,
Therefore,
So, the correct option is B.
Use separation immediately
Given: Each mass moves in a circle of radius , so the two masses are separated by .
Find: The angular speed .
The mutual gravitational force is
and this must equal the centripetal force on one mass,
So,
which gives
The correct option is B. The key shortcut is to notice immediately that the separation is , not .
Taking the gravitational separation as instead of . This is wrong because is the radius of each particle's circular path about the centre of mass, so the two particles are actually apart. Always use separation in Newton's law of gravitation.
Using centripetal force as for one particle. This is incorrect because each particle moves in a circle of radius , not . Use for the centripetal force of each mass.
Assuming one particle is fixed and the other revolves around it. That changes the physical setup and gives the wrong radius and force balance. Here both identical masses revolve about their common centre of mass symmetrically.
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