In troposhere, temperature varles linearly with elevation as `T=T_(0)-ay,` where `T_(0)` is the temperature at lthe earth's surface, then

Temperature of a body varies with time as T=(T_(0)+at^(2)+beta sin)K , where T_(0) is the temperature in at t=0sec. & alpha=2//piK//s^(2)&beta=-4K . then rate of change of temperature ((dT)/(dt)) at t=

If 2 mol of an ideal monatomic gas at temperature T_(0) are mixed with 4 mol of another ideal monatoic gas at temperature 2 T_(0) then the temperature of the mixture is

A uniform tube of volume V contains an ideal monatomic gas at a uniform pressure P the temperature of the gas varies linearly along te length of the tube ad T and 2 T are the temperature at the ends.

The resistance of an electrolyte varies with temperature T as R_(T) = (R_(O))/(1 + alpha T) , where R_(0) and are constants. A constant potential difference V is applied to the two electrodes (each of surface area A ) which are dipped in this electrolyte. If T_(0) is the temperature of the surroundings, the loss of heat to the surroundings per unit surface area put unit time is governed by the same relation H = k (T - T_(0)) A , the steady state temperature is

[" Temperature of a resistance at "],[" temperature "t^(0)C" is "R=R_(0)(1+at+bt^(2))" ."],[" Here "R_(0)" is the temperature at "0^(0)C" ,the "],[" temperature coefficient of resistance at "],[" temperature "t" is: "]

If for a thermocouple T_(n)) is the neutral temperature, T_(c ) is the tempreture of the cold junction and T_(i)) is the temperature of inversion, then

Two moles of an ideal mono-atomic gas undergoes a thermodynamic process in which the molar heat capacity 'C' of the gas depends on absolute temperature as C=(RT)/(T_(0)) , where R is gas consant and T_(0) is the initial temperature of the gas. ( V_(0) is the initial of the gas). Then answer the following questions: The equation of process is

One mole of an ideal monoatomic gas undergoes the process T=T_(0)+4V , where T_(0) is initial temperature. Find (i) Heat capacity of gas as function of its volume. (ii) The amount of heat transferred to gas if its volume increases from V_(0) to 4V_(0) .