Calculate the value of solar constant at the distance of Jupiter, which is `5.2AU` away from the sun. Hence calculate the temperature of a black body on Jupiter's Stefan's law.

Calculate the temperature of the black body from given graph.

Calculate the solar constant on a planet which is approximately 5 A.U. from the sun. Assume the solar constant on earth as 1400 Wm^(-2) .

The distance of planet Jupiter from the Sun is 5.2 times that of the earth. Find the period of revolution of Jupiter around the Sun.

A planet of radius r_(0) is at a distance r from the sun (r gtgt r_(0)) . The sun has radius R. Temperature of the planet is T_(0) , and that of the surface of the sun is T_(s) . Calculate the temperature of another planet whose radius is 2r_(0) and which is at a distance 2r from the sun. Assume that the sun and the planets are black bodies.

Calculate the value of magnetic field at a distance of 2 cm from a very long straight wire carrying a current 5 A

The solar energy received by the Earth persquare metre per minute is 8.315 xx 10^(4)Jm^(-2)min^(-1) . If the radius of the Sun is 7.5 xx 10^(5) km and the distance of the Earth from the Sun is 1.5 xx10^(8) km, calculate the surface temperature of Sun. Assume the Sun as a perfect black body. Given that Stefen constanta sigma = 5.7 xx 10^(-8)Wm^(-2)K^(-4).

Calculate the displacement and distance travelled by the body in 5 s, from the adjoining velocity-time graph

(a) What is solar constant ? What is the value of solar constant ? (b) If the energy received by 5 m^(2) area in 10 minutes is 4200 kJ, calculate the value of solar constant.

The mass of planet Jupiter is 1.9xx10^(7)kg and that of the Sun is 1.9x10^(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) .