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

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

When the temperature of a black body increases, it is observed that the wavelenght corresponding to maximum energy changes from 0.26 mum to 0.13 mum . The ration of the emissive power of the body at the respective temperature is

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

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

If temperature of a black body increases then what does happen to the wavelength with which maximum energy is associated ?

If the temperature of a black body is increased, then the maximum of the spectrum will

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