Calculate the temperature of the black body from given graph.

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.

A black body radiated maximum energy around a particular wavelength at a given temperature. If the temperature of the black body is now changed so that it radiates maximum energy around a wavelength n time the original wavelength (n lt 1) then power radiate by it will increases by a factor of:

At high temperature black body spectrum is .

In a dark room with ambient temperature T_(0) , a black body is kept at a temperature T . Keeping the temperature of the black body constant (at T ), sunrays are allowed to fall on the black body through a hole in the roof of the dark room. Assuming that there is no change in the ambient temperature of the room, which of the following statements (s) is/are correct ?

For a black body at temperature 527^(@)C , its radiating power is 60 W and temperature of surrounding is 127^(@)C . If the temperature of the black body iss changed to 927^(@)C , then its radiating power will be:-

What will happen to the emission rate if the temperature of a black body is increased from 200 K to 400 K?

The energy emitted per second by a black body at 27^(@)C is 10 J. If the temperature of the black body is increased to 327^(@)C , the energy emitted per second will be