When the temperature of black body rises, then the wavelength corresponding to the maximum intensity `(lamda_(m))`

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

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:

When the temperature of a black body increases, it is observed that the wavelength corresponding to maximum energy changes from 0.26mum to 0.13mum . The ratio of the emissive powers of the body at the respective temperatures is

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 ?

If the temperature of the body is increases from 27°C to 327°C then wavelength corresponding to maximum intensity becomes

The temperature (approx) of the body omitting wavelength 0.3 mum corresponding to maximum intensity is

Statement I: As the temperature of the black body increases, the wavelength at which the spectral intensity (E_lamda) is maximum decreases. Statement II: The wavelength at which the spectral intensity will be maximum for a black body is proportional to the fourth power of its absolute temperature.

If the temperature of any ideal black body is halved, then the wavelength of maximum emission will be

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.

Statement-1 : When temperature of a black body is halved, wavelength corresponding to which energy radiate is maximum become twice. Statement-2 : This is as per Wien's Law.