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

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

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.

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

If wavelengths of maximum intensity of radiations emitted by the sun and the moon are 0.5xx10^(-6)m " and " 10^(-4) m respectively, the ratio of their temperature is ……………

If wavelengths of maximum intensity of radiations emitted by the sun and the moon are 0.5xx 10^(-6)m and 10^(-4)m respectively, the ratio of their temperatures is

Find the wavelength at which a black body radiates maximum energy, if its temperature is 427^(@) C. (Wein's constant b=2.898 xx 10^(-3) mK )

If wavelength of maximum intensity of radiation emitted by Sun and Moon are 0.5 xx 10^(-6) m and 10^(-4) m respectively, then the ratio of their temperature is

The maximum radiant power of a certain star is at wavelength 600 nm. The wien displacement law constant is 2.898 xx 10^(-3) m.K. Estimate the temperature of the surface of the star. Assume the star to be a blackbody radiator.

The wavelengths corresponding to maximum energy density of radiation, emitted by the moon and the sun are 10^(-4)m and 4xx10^(-7)m respectively. What is the ratio of their temperatures ?

A hot body having the surface temperture 1127^(@)C Determine the wavelength at wchich it radiates maximum energy . Given , Wien' s constant =2.9xx10^(-3) mK .