Advertisements
Advertisements
प्रश्न
At what rate should the earth rotate so that the apparent g at the equator becomes zero? What will be the length of the day in this situation?
उत्तर
The apparent acceleration due to gravity at the equator becomes zero.
i.e., g' = g − ω2R = 0
⇒ g = ω2R
\[\Rightarrow \omega = \sqrt{\frac{g}{R}} = \sqrt{\frac{9 . 8}{6400 \times {10}^3}}\]
\[ \Rightarrow \omega = \sqrt{\frac{9 . 8 \times {10}^{- 5}}{6 . 4}} = \sqrt{1 . 5 \times {10}^{- 6}}\]
\[ \Rightarrow \omega = 1 . 2 \times {10}^{- 3} \text{ rad }/s\]
\[ \therefore T = \frac{2\pi}{\omega} = \frac{2 \times 3 . 14}{1 . 2 \times {10}^{- 3}}\]
\[ = \frac{6 . 28}{1 . 2 \times {10}^{- 3}}\]
= 1 . 41 h
APPEARS IN
संबंधित प्रश्न
Suppose there existed a planet that went around the sun twice as fast as the earth.What would be its orbital size as compared to that of the earth?
No part of India is situated on the equator. Is it possible to have a geostationary satellite which always remains over New Delhi?
As the earth rotates about its axis, a person living in his house at the equator goes in a circular orbit of radius equal to the radius of the earth. Why does he/she not feel weightless as a satellite passenger does?
The time period of an earth-satellite in circular orbit is independent of
Two satellites A and B move round the earth in the same orbit. The mass of B is twice the mass of A.
A satellite of mass 1000 kg is supposed to orbit the earth at a height of 2000 km above the earth's surface. Find (a) its speed in the orbit, (b) is kinetic energy, (c) the potential energy of the earth-satellite system and (d) its time period. Mass of the earth = 6 × 1024kg.
State the conditions for various possible orbits of satellite depending upon the horizontal/tangential speed of projection.
Answer the following question in detail.
Obtain an expression for the binding energy of a satellite revolving around the Earth at a certain altitude.
Answer the following question in detail.
Two satellites A and B are revolving round a planet. Their periods of revolution are 1 hour and 8 hour respectively. The radius of orbit of satellite B is 4 × 104 km. Find radius of orbit of satellite A.
Solve the following problem.
Calculate the value of the universal gravitational constant from the given data. Mass of the Earth = 6 × 1024 kg, Radius of the Earth = 6400 km, and the acceleration due to gravity on the surface = 9.8 m/s2.
The ratio of energy required to raise a satellite of mass 'm' to a height 'h' above the earth's surface of that required to put it into the orbit at same height is ______.
[R = radius of the earth]
Which of the following statements is CORRECT in respect of a geostationary satellite?
What is the minimum energy required to launch a satellite of mass 'm' from the surface of the earth of mass 'M' and radius 'R' at an altitude 2R?
Two satellites A and B go round a planet P in circular orbits having radii 4R and R respectively. If the speed of the satellite A is 3v, the speed of satellite B is ____________.
In the case of earth, mean radius is 'R', acceleration due to gravity on the surface is 'g', angular speed about its own axis is 'ω'. What will be the radius of the orbit of a geostationary satellite?
A satellite is to revolve round the earth in a circle of radius 9600 km. The speed with which this satellite be projected into an orbit, will be ______.
An artificial satellite is moving in a circular orbit around the earth with a speed equal to half the magnitude of escape velocity from the earth. If the satellite is stopped in its orbit and allowed to fall freely onto the earth, the speed with which it hits the surface ______ km/s.
[g = 9.8 ms-2 and Re = 6400 km]
A satellite is revolving around a planet in a circular orbit close to its surface and ρ is the mean density and R is the radius of the planet, then the period of ______.
(G = universal constant of gravitation)
