A planet is at an average distance d from the sun and its average surface temeperature is T. Assume that the planet receives energy only from the sun and loses energy only through radiation from the surface. Neglect atmospheric effects. If `Tpropd^(-n)`, the value of n is

Two planets at mean distance d_(1) and d_(2) from the sun and their frequencies are n and n respectively then

If r denotes the mean distance of a planet from the sun and T is the time period of planet, then

A planet is at R distance from sun and its time period of revolution is T. What will be its new time period of revolution if it brought 0.5 R distance closer to sun ?

Statement-I: When a planet is at maximum distance from the sun, its speed is minimum. Statement-II: The motion of planet around the sun does not follow the law of conservation of angular momentum.

Assume that a planet radiates heat at a rate proportional to the fourth power of its surface temperature T and that the temperature of the planet is such that this loss is exactly compensated by the heat gained from the sun. Show that other things remaining the same, a planet's surface temperature will vary inversely as the square root of its distance from the sun.

The surface temperature of the sun is T_(0) and it is at average distance d from a planet. The radius of the sun is R . The temperature at which planet radiates the energy is