A solid copper sphere (density `=8900kgm^(-3)` and specific heat `C=390Jkg^(-1)K^(-1)`) of radius `r=10cm` is at an initial temperature `T_(1)=200K`. It is then suspended inside an chamber whose walls are at almost `OK`. Calculate the time required for the temperature of the sphere to drop to `T_(2)=100 K`, `sigma=5.67xx10^(-8)Wm^(-2)K^(-4)`.

A solid copper sphere (density rho and specific heat c) of radius r at an initial temperature 200K is suspended inside a chamber whose walls are at almost 0K. The time required for the temperature of the sphere to drop to 100K is …….

A solid copper sphere of density rho , specific heat c and radius r is at temperature T_1 . It is suspended inside a chamber whose walls are at temperature 0K . What is the time required for the temperature of sphere to drop to T_2 ? Take the emmissivity of the sphere to be equal to e.

A solid copper shere of density rho specific heat c and radius r is at temperature T_(1) It is suspended inside a chamber whose walls are at temperature 0 K The time required for the temperature of sphere to drop to T_(2) is (rrhoc)/(xesigma)((1)/(T_(2)^(3))-(1)/(T_(1)^(3))) Find the value of x? Take the emmissivity of teh sphere to be equal to e .

The power of black body at temperature 200 K is 544 W .Its surface area is (sigma=5.67xx10^(-8)Wm^(-2)K^(-2))

The amount of heat energy required to raise the temperature of 1 g of Helium at NTP, from T_(1) K to T_(2) K is :

The amount of heat energy required to raise the temperature of 1 g of Helium at NTP , from T_(1)K to T_(2)K is

If the sun's surface radiates heat at 6.3 xx 10^(7) Wm^(-2) . Calculate the temperature of the sun assuming it to be a black body (sigma = 5.7 xx 10^(-8)Wm^(-2)K^(-4))

A solid sphere of radius 'R' density rho and specific heat 'S' initially at temperature T_(0) Kelvin is suspended in a surrounding at temperature 0K. Then the time required to decrease the temperature of the sphere from T_(0) to (T_(0))/(2) kelvin is (Assume sphere behaves like a black 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) .