If the wavelength corresponding to maximum energy radiated from the moon is 14 micron, and wien's constant is `2.8xx10^(-3)mK`, then temperature of moon is

If the wavelength corresponding to maximum energy radiated from the moon is 14 micron , and Wien 's constant is 2.8 xx 10^(-3) m K , then temperature of moon is

For the moon, the wavelength corresponding to the maximum spectral emissive power is 14 microns. If the Wien's constant b=2.884 xx10^(-3)mK , then the temperature of the moon is close to

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 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 = 2.892 xx 10^-3 mk ?

The wavelength of the radiation emitted by a black body is 1 mm and Wien's constant is 3xx10^(-3) mK. Then the temperature of the black body will be

Calculate the colour temperautre of the sun assuming that the wavelength of maximum energy in the solar spectrum is 0.48 micron and the Wien's constant is 0.228xx10^(-2) mK.

Light from the moon, is found to have a peak (or wevelenght of maximum emission) at lambda = 14 mu m . Given that the Wien's constant b equals 2.8988 xx 10^(-3) mK , estimate the temperature of the moon.

Calculate the effective temperature of the sun . Given that the wavelength of maximum energy in the solar spectrum is 475 mm and Wien's constant is 2.898xx10^(-3) mK.

The wavelength of maximum energy released during an atomic axplosion was 2.93xx10^(-10)m . Given that Wien's constant is 2.93xx10^(-3)m-K , the maximum temperature attained must be of the order of