Suppose the gravitational force varies inversely as the `n^(th)` power of distance. Then the time period of a planet in circular orbit of radius R around the sun will be proportional to

Time period of a satellite in a circular obbit around a planet is independent of

The time period of a satellite in a circular orbit of radius R is T. The radius of the orbit in which time period is 8 T is

If the distance between the earth and sun becomes 1/4 ^(th) , then its period of revolution around the sun will become

The earth moves round the sun in a near circular orbit of radius 1.5 xx 10^11 m. Its centripetal acceleration is

If the gravitational force were proportional to 1/r , then a particle in a circular orbit under such a force would have its original speed:

The mass density of a spherical galaxy varies as K/r over a large distance 'r' from its centre. In that region, a small star is in a circular orbit of radius R. Then the period of revolution, T depends on R as:

The orbital speed of an electron orbiting around the nucleus in a circular orbit of radius r is v. Then the magnetic dipole moment of the electron will be

The mass of planet Jupiter is 1.9xx10^(27)kg and that of the Sun is 1.9xx10^(30)kg . The mean distance of Jupiter from the Sun is 7.8xx10^(11) m. Calculate te gravitational force which Sun exerts on Jupiter. Assuming that Jupiter moves in circular orbit around the Sun, also calculate the speed of Jupiter G=6.67xx10^(-11)Nm^(2)kg^(-2) .

The magnetic moment of a current (i) carrying circular coil of radius (r) and number of turns (n) varies as

The square of time period of revolution around the sun is diretly proportional to the ______of the planet from the sun .