The power radiated by a blackbody is P at a certain temperature. If power radiated by this body becomes `1/16 th` the times. then wavelength corresponding to maximum intensity becomes

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

Two spherical black bodies A and B are emitting radiations at same rate. The radius of B is doubled keeping radius of A fixed. The wavelength corresponding to maximum intensity becomes half for A white it ramains same for B. Then, the ratio of rate radiation energy emitted by a and is B is

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

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

A black body emits radiation of maximum intensity at a wavelength of 5000A when the temperature of the body is 1227^(@) C. If the temperature of the body is increased by 1000^(@) C, calculate the wavelength corresponding to the maximum intensity.

A black body emits maximum radiation of wavelength lambda_(1) at a certain temperature T_(1) . On increasing the temperature, the total energy of radiation emitted is increased 16 times at temperature T_(2) . If lambda_(2) is the wavelength corresponding to which maximum radiation is emitted at temperature T_(2) . Calculate the value of ((lambda_(1))/(lambda_(2))) .

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 .

The power radiated by a black body is P, and it radiates maximum energy around the wavelength lambda_(0) . If the temperature of the black body is now changed so that it radiates maximum energy around a wavelength 3lambda_(0)//4 , the power radiated by it will increase by a factor of