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

The temperature of two bodies A and B are respectively 727^(@)C and 327^(@)C . The ratio H_(A) : H_(B) of the rates of heat radiated by them is

The sphere of radii 8 cm and 2 cm are cooling. Their temperatures are 127^(@)C and 527^(@)C respectively . Find the ratio of energy radiated by them in the same time

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

The two ends of a metal rod are maintained temperatures 100^@C and 110^@C . The rate of heat flow in the rod is found to be 4.0 J/s . If the ends are maintained at temperatures 200^@C and 210^@C , the rate of heat flow will be

Compare rates of loss of heat by the body at temperature 527^@C and 127^@C . Temperatue of surrounding is 27^@C .

A black body emits radiations of maximum intensity at a wavelength of 5000 A, when the temperature of the body is 1227° C. If the temperature of the body is increased by 2227 °C, the maximum intensity of emitted radiation would be observed at

Compare the ratio of radiation of metal sphere at 627^@C and 327^@C .

The surface temperature of a black body is 1200 K. What is the wavelength corresponding to maximum intensity of emission of radiation if Wien's constant b = 2.892 xx 10^-3 mk ?

Consider two hot bodies B_(1) and B_(2) which have temperature 100^(@)"C" and 80^(@)"C" respectively at t = 0. The temperature of surroundings is 40^(@)" C" . The ratio of the respective rates of cooling R_(1) and R_(2) of these two bodies at t = 0 will be

The ratio of masses of two metal spheres A and B is 8 : I. If their temperatures are 2000 K and 1000 K respectively, then the ratio of the rates of their energy emission will be