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 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.

The efficiency of a heat engine if the temperature of source 227^(@)C and that of sink is 27^(@)C nearly?

Two bodies A and B are kept in an evacuated chamber at 27^@C . The temperatures of A and B are 327^@ and 427^@C and respectively. The ratio of rates of loss of heat from A and B will be–

Two identical spheres A and B are suspended in an air chamber which is maintained at a temperature of 50^@C . Find the ratio of the heat lost per second from the surface of the spheres if a. A and B are at temperatures 60^@C and 55^@C , respectively. b. A and B are at temperatures 250^@C and 200^@C , respectively.

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

The temperature of a body is increased from –73°C to 327°C. Then the ratio of emissive power is –

A black body radiates 20 W at temperature 227^(@)C . If temperature of the black body is changed to 727^(@)C then its radiating power wil be

Two identical metal balls at temperature 200^(@)C and 400^(@)C kept in air at 27^(@)C . The ratio of net heat loss by these bodies is

The temperatures of two bodies A and B are 727^(@)C and 127^(@)C . The ratio of rate of emission of radiations will be