Two bodies A and B having equal surface areas are maintained at temperatures `10^(@)C` . And `20^(@)C` . The thermal radiation emitted in a given time by A and B are in the ratio

Two black bodies A and B have equal surface areas and are maintained at temperatures 27^@ C and 177^@ C respectively. What will be the ratio of the thermal energy radiated per second by A to that by B?

Two black bodies A and B have equal surface areas and are maintained at temperatures 27° C and 177° C respectively. What will be the ratio of the thermal energy radiated per second by A to that by B ?

Two bodies A and B are kept in evacuated vessels maintained at a temperature of 27^(@)C . The temperature of A is 527^(@)C and that of B is 127^(@)C . Compare the rates at which heat is lost from A and B.

Two bodies A and B having equal outer surface areas have thermal emissivity 0.04 and 0.64 respectively. They emit total radiant power at the same rate. The difference between wavelength corresponding to maximum spectral radiance in the radiation from B and that from A is 2 mum . If the temperature of A is 6000 K, then

Two bodies A and B are placed in an evacuated vessel maintained at a temperature of 27^(@)C , the temperature of A is 327^(@)C and that of B is 227^(@)C . Then the ratio of heat loss by body A and B is

Two bodies A and B are placed in an evacuated vessel maintained at a temperature of 27^(@)C , the temperature of A is 327^(@)C and that of B is 227^(@)C . Then the ratio of heat loss by body A and B is

Two bodies hae temperatures as 227^(@)C and 727^(@)C ratio of heat radiated by them will be

Two bodies A and B placed in an evacuated vessel maintained at a temperature of 27^@C , the temperature of A is 327^@C and that of B is 227^@C . Then the ratio of heat loss by body A and B is

Two bodies Aand B of equal surface area have thermal emissivities of 0.01 and 0.81 respectively . The two bodies are radiating energy at the same rate. Maximum energy is radiated from the two bodies A and B at wavelength lambda _(A) and lambda _(B) respectively . Difference in these two wavelengths is 1 mu m . If the temperature of the body A is 5802 K, then value of lambda_(B) is