A solid at temperature `T_(1)` is kept in an evacuated chamber at temperature `T_(2)gtT_(1)` . The rate of increase of temperature of the body is proportional to

A solid at temperature T_(1) is kept in an evacuated chamber at temperature T_(2)gtT_(1) . The rate of increase of temperature of the body is propertional to

A copper block of mass 'm' at temperature 'T_(1)' is kept in the open atmosphere at temperature 'T_(2)' where T_(2) gt T_(1) . The variation of entropy of the copper block with time is best illustrated by

One end of a rod of length L and crosssectional area A is kept in a furnace at temperature T_(1) . The other end of the rod is kept at a temperature T_(2) . The thermal conductivity of the matrieal of the rod is K and emissivity of the rod is e. It is gives that T_(!)=T_(s)+DeltaT , where DeltaTltlt T_(s),T_(s) is the temperature of the surroundings. If DeltaTprop(T_(1)-T_(2)) find the proportional constant, consider that heat is lost only by rediation at the end where the temperature of the rod is T_(1) .

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 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)

Two bars of same length and same cross-sectional area but of different thermal conductivites K_(1) and K_(2) are joined end to end as shown in the figure. One end of the compound bar it is at temperature T_(1) and the opposite end at temperature T_(2) (where T_(1) gt T_(2) ). The temperature of the junction is

One end of rod of length L and cross-sectional area A is kept in a furance of temperature T_(1) . The other end of the rod is kept at at temperature T_(2) . The thermal conductivity of the material of the rod is K and emissivity of the rod is e . It is given that T_(2)=T_(S)+DeltaT where DeltaT lt lt T_(S) , T_(S) being the temperature of the surroundings. If DeltaT prop (T_(1)-T_(S)) , find the proportionality constant. Consider that heat is lost only by radiation at the end where the temperature of the rod is T_(2) .

The ends of a metal rod are kept at temperatures theta_1 and theta_2 with theta_2gttheta_1 . The rate of flow of heat along the rod is directly proportional to

Three Carnot engines operate in series between a heat source at a temperature T_(1) and a heat sink at temperature T_(4) (see figure). There are two other reservoirs at temperature T_(2) and T_(3) , as shown, with T_(1)gtT_(2)gtT_(3)gtT_(4) . The three engines are equally efficient if :

A black body of temperature T is inside a chamber of temperature T_(0) Now the closed chamber is slightly opened to Sun that temeperature of black body (T) and chamber (T_(0)) remain constant .