The absolute temperatures of two black bodies are 2000 K and 3000 K respectively. The ratio of wavelengths corresponding to maximum emission of radiation by them will be

The surface temperature of a black body is 1200 K. What is the wavelength corresponding to maximum intensity of emission of radiation if Wien's constant b = 2.892xx10^(-3)mK ?

The radiation emitted by a star A is 10,000 times that of the sun. If the surface temperatures of the sun and the star A are 8000 K and 2000 K respectively. The ratio of the radii of the star A and the sun is

If the temperature of a black body is increased then the wavelength corresponding to the maximum emission will

The radiation emitted by a star A is 1000 times that of the sun. If the surface temperature of the sun and star A are 6000 K and 2000 K respectively. The ratio of the radii of the star A and the sun is:

The radiation emitted by a star A is 10,000 times that of the sun. If the surface temperatures of the sun and the star A are 6000 K and 2000 K respectively, the ratio of the radii of the star A and the sun is

The radiation emitted by a star A is 100 times that of the sun. If the surface temperatures of the sun and the star are 6000 K and 2000 K respectively, then the ratio of the radii of the star and the sun is

The temperature of one of the two heated black bodies is T_(1) = 2500K . Find the temperature of the other body if the wavelength corresponding to its maximum emissive capacity exceeds by Delta lambda = 0.50mu m the wavelength corresponding to the maximum emissive capacity of the first black body.

When the temperature of a black body increases, it is observed that the wavelength corresponding to maximum energy changes from 0.26 mu m . The ratio of the emissive powers of the body at the respective temperature is: