Calculate the energy radiated in one minute by a blackbody of surface area 200 `cm^2` at 127 `""^(@)C ( sigma= 5.7 xx 10^(-8) J m^(-2) s^(-1) K^(-4))`

Calculate the energy radiated in one minute by a blackbody of surface area 100 cm^(2) when it is maintained at 127^(@)C .

Consider the sun to be a perfect sphere of radius 6.8 xx 10^(8)m . Calculate the energy radiated by sun in one minute. Surface temperature of the sun = 6200 K . Stefan's constant = 5.67 xx 10^(-8) J m^(-2) s^(-1) K^(-4) .

The surface temperature of the sun is 6000K . If we consider it as a perfect black body, calculate the energy radiated away by the sun per second. Take radius of the sun =6.92xx10^(5)km and sigma=5.67xx10^(-8)Jm^(-2)s^(-1)K^(-4)

The energy of 6000 J is radiated in 10 minutes by a body of surface area 200 cm^(2) . Find the emissive power of the body.

Calculate the temperature (in K) at which a perfect black body radiates energy at the rate of 5.67W cm^(-2) . Given sigma = 5.67 xx 10^(8)Wm^(-2)K^(-4) .

The radiant power of a furnace of surface area of 0.6m^(2) is 34.2KW The temperature of the furance s [sigma = 5.7 xx 10^(-8) Wm^(-2) K^(-4) .

Assume that the total surface area of a human body is 1-6m^(2) and that it radiates like an ideal radiator. Calculate the amount of energy radiates per second by the body if the body temperature is 37^(@)C . Stefan contant sigma is 6.0xx10^(-s)Wm^(-2)K^(-4) .

A black ened metal sphere of radius 7 cm is encllosed in as evacuated chamber maintained at a temperature of 27^(@)C . At what rate must energy be supplied to the sphere so as to keep its temperature constant at 127^(@)C ? sigma=5.7xx10^(-8) W m^(-2) K^(-4) .