A black body is at `727^(@)` C. It emits energy at a rate which is proportional to:

A black body is at a temperature 300 K . It emits energy at a rate, which is proportional to

A black body is at temperature of 500 K . It emits energy at rate which is proportional to

Emissive power of an ideal black body at 127^(@)C is E. the temperature at which it increases to 102% is

A black body at a temperature of 227^(@)C radiates heat energy at the rate of 5 cal/ cm^(2) -sec. At a temperature of 727^(@)C , the rate of heat radiated per unit area in cal/ cm^(2) -sec will be

The rate of diffusion of a gas is proportional to

A black body at 1227^(@)C emits radiations with maximum intensity at a wavelength of 5000 Å . If the temperature of the body is increased by 1000^(@) , the maximum intensity will be observed at

The rectangular surface of area 8 cm xx 4 cm of a black body at temperature 127^(@)C emits energy E per section if length and breadth are reduced to half of the initial value and the temperature is raised to 327^(@)C , the ratio of emission of energy becomes

The energy radiated by a black body is directly proportional to :

A black body at 227^(@)C radiates heat at the rate of 7 cal cm^(-2) s^(-1) . At a temperature of 727^(@)C , the rate of heat radiated in the same unit will be

A black body initially at 27^(@) C is heated to 327^(@) C. How many times is the total radiation emitted at the higher temperature than that emitted at the lower temperature ? What is the wavelength of the maximum energy radiation at the higher temperature ? Wien's constant = 2.898xx10^(-3) mK.