A satellite is orbiting the earth close to its surface. A particle is to be projected from the satellite to just escape from the Earth. The escape speed from the Earth is \(v_e.\) Its speed with respect to the satellite:

1.	will be less than \(v_e\)
2.	will be more than \(v_e\)
3.	will be equal to \(v_e\)
4.	will depend on the direction of the projection

Let V and E denote the gravitational potential and gravitational field at a point. It is possible to have:

(a) V = 0 and E = 0

(b) V = 0 and E ≠ 0

(c) V ≠ 0 and E = 0

(d) V ≠ 0 and E ≠ 0

Choose the correct option:

1. (a) and (b)

2. (b) and (c)

3. (c) and (d)

4. All of these

Inside a uniform spherical shell:

Choose the correct option:

A uniform spherical shell gradually shrinks maintaining its shape. The gravitational potential at the centre

1. increases

2. decreases

3. remains constant

4. oscillates

Consider a planet moving in an elliptical orbit around the sun. The work done on the planet by the gravitational force of the sun:

Choose the correct option:

Two satellites A and B move around the earth in the same orbit. The mass of B is twice the mass of A. Then:

Which of the following quantities remain constant in a planetary motion (consider elliptical orbits) as seen from the sun?

A particle is kept at rest at a distance R (earth's radius) above the earth's surface. The minimum speed with which it should be projected so that it does not return is

1. \(\sqrt\frac{GM}{4R}\)

2. \(\sqrt\frac{GM}{2R}\)

3. \(\sqrt\frac{GM}{R}\)

4. \(\sqrt\frac{2GM}{R}\)

The kinetic energy needed to project a body of mass m from the earth's surface to infinity is

1. \(\frac14\) mgR

2. \(\frac12\) mgR

3. mgR

4. 2 mgR

A body is suspended from a spring balance kept in a satellite. The reading of the balance is W₁ when the satellite goes in an orbit of radius R and is W₂ when it goes in an orbit of radius 2R.

1. W₁ = W₂

2. W₁ < W₂

3. W₁ > W₂

4. W₁ ≠  W₂