For maximum radiant energy, from the moon the corresponding wavelength is 14 micron, If wien constant is b= `2892 xx 10^(-6)` mK, then temperature of the moon is

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

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

Two bodies A and B have thermal emissivities of 0.01 and 0.81 respectively. The outer surface areas of the two bodies are same. The two bodies emit total radiant power at the same rate. The wavelength lambda_B corresponding to maximum spectral radiancy from B is shifted from the wavelength corresponding to maximum spectral radiancy in the radiation from A by 1.0 mum . If the temperature of A is 5802 K, calculate (a) the temperature of B, (b) wavelength lambda_B .

Two bodies A and B have thermal emissivities of 0.01 and 0.81 respectively. The outer surface areas of the two bodies are same. The two bodies emit total radiant power at the same rate. The wavelength lambda_B corresponding to maximum spectral radiancy from B is shifted from the wavelength corresponding to maximum spectral radiancy in the radiation from A by 1.0 mum . If the temperature of A is 5802 K, calculate (a) the temperature of B, (b) wavelength lambda_B .

From two diametrically opposite points A and B on earth, moon is observed. The angle theta subtended at the moon by the two directions of observation is 1^@ 54^1 . If radius of earth is 0.638 xx 10^7 m, find the distance of the moon from the earth.

A black body at 1373 ^@C emits maximum energy corresponding to a wavelength of 1.78 microns. The temperature of the moon for which lamda_m=14 micron wood be

Power radiated by a black body is P_0 and the wavelength corresponding to maximum energy is around lamda_0 , On changing the temperature of the black body, it was observed that the power radiated becames (256)/(81)P_0 . The shift in wavelength corresponding to the maximum energy will be

Power radiated by a black body is P_0 and the wavelength corresponding to maximum energy is around lamda_0 , On changing the temperature of the black body, it was observed that the power radiated becames (256)/(81)P_0 . The shift in wavelength corresponding to the maximum energy will be

The wavelength lambda_(m) of maximum intensity of emission of solar radiation is lambda_(m) = 4753 Å and from moon is lambda_(m) = 14 mum The surface temperature of sun and moon are (given b = 2.898 xx 10^(-3) meter/Kelvin)

According to Wien's law, the wavelength (lambda) corresponding to the maximum light intensity emitted from a blackbody at temperature T is given by lambdaT=2.9xx10^(-3) mK . Calculate the surface temperature of a star whose blackbody radiation has a peak intensity corresponding to then n=1 rarr n=2 excitation of hydrogen.