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Question

Two bodies of masses m and 4m are placed at a distance of r. The gravitational potential at a point on the line joining them where the gravitational field is zero is


A

-4Gmr

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B

-6Gmr

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C

-9Gmr

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D

Zero

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Solution

The correct option is C

-9Gmr


Step 1: Given data

Mass of a first body A is = m

Mass of a second body B is = 4m

Both masses are separated by a distance = r

If a point mass of one unit is placed along the axis connecting the centers of the two objects. Therefore, Ccan be regarded as a neutral point, located on this line and at which the point mass is not subject to the effects of gravity.

Then this neutral point Cis situated at, x distance from A and r-x distance from B.

We have to find the net gravitational potential.

Step 2: Formula to be used

The gravitational force between a given mass and a unit mass is called the gravitational field intensity.

If the force of gravity between two objects is determined by,

F=Gm1m2r2

Here, m1 and m2 are the mass of two objects and r is the distance between their centers and G is the universal gravitational constant.

The gravitation field intensity Eg of an object, consider m2=1, we get

Eg=Gmr2

Because of mass A, the gravitational field is,

EgA=Gmx2

Because of mass B, the gravitational field at point C is,

EgB=4Gmr-x2

So, the total gravitational field at this point is zero, we get,

EgA+EgB=0

Step 3: Find the point lying on the line joining the point masses where the net gravitational force is zero.

Because the directions of the fields produced at C by the two masses are opposite, the outcome of adding them together is zero.

solution

So,

4Gmr-x2=Gmx2

4(rx)2=1x2

The above expression can be written as,

2(rx)=1x

rx=2x

r=3x

x=r3
And

rx=2r3

Step 4: Calculating the net gravitational potential

The gravitational potential at this point VC, is

VC=VA+VB
We know that,
V=Gmr
The gravitational potential of A at C is,
VA=Gmx
Substitute the value of x, we get,
VA=Gmr3

=3Gmr
The gravitational potential of B at point C is,
VB=4Gmrx
Substituting the value of x, we get,

VB=4Gmrr3

=3×4Gm2r
=6Gmr
Therefore,
VC=3Gmr6Gmr
=-9Gmr
Hence, option (C) is the correct answer.


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