Assertion : On cooling , ammonia liquifies first whereas `CO_(2)` requires more cooling .
Reason : Critical temperatures of ammonia and carbon dioxide are 405.5 K and 304.10 K respectively .

Assertion :- On cooling ,ammonia lirquifies first whereas CO_(2) requires more cooling. Reason :- Critical temperatures of ammonia and carbon dioxide are 405.5 K and 304.10 K respectively.

Gases possess characteristic critical temperature which depends upon the magnitude of intermolecular forces between the gas particles. Critical temperatures of ammonia and carbon dioxide are 405.5 K and 304.10 K respectively. Which of these gases will liquify first when you start cooling from 500 K to their critical temperature ?

Gases possess characteristic critical temperature which depends upon the magnitude of intermolecualr forces between the gas particles, critical temperatures of ammonia and carbon dioxide are 405.5 K and 304.10 K respectively. Which of these gases will liquefy first when you start cooling from 500 K to their critical temperature ?

Assertion : NH3 is liquidities more easily than CO_(2) . Reason : Critical temperature of NH3 is more than CO_(2) .

Assertion : CO_(2) gas stronger intermolecular forces than CH_(4) Reason : Critical temperature of CO_(2) is more.

Assertion : Critical temperature of CO_(2)" is "304 K, it cannot be liquefied above 304 K. Reason : At a certain temperature, volume prop 1// pressure.

A solution containing 0.1 mol of naphthalene and 0.9 mol of benzene is cooled out until some benzene freezes out. The solution is then decanted off from the solid and warmed upto 353 K where its vapour pressure was found to be 670 mm . The freezing point and boiling point of benzene are 278.5 K and 353 K respectively, and its enthalpy of fusion is 10.67 KJ "mol"^(-1) . Calculate the temperature to which the solution was cooled originally and the amount of benzene that must have frozen out. Assume ideal behaviour.

In the circuit shown the resistance R is kept in a chamber whose temperature. is 20^(@) C which remains constant. The initial temperature and resistance of R is 50^(@)C and 15 Omega respectively. The rate of change of resistance R with temperature is (1)/(2)Omega//^(@)C and the rate of decrease of temperature of R is In (3//100) times the temperature difference from the surrounding (Assume the resistance R loses heat only in accordance with Newton's law of cooling) If K is closed at t = 0, then find the (a) value of. R for which power dissipation in it is maximum. (b) temperature of R when power dissipation is maximum (c) time after which the power dissipation will be maximum

Assertion At triple point, three stated (solid, liquid and gas) may co-exist simulaneously. Reason For water, the values of pressur and temperature corresponding to triple point are 10 mm of Hg and 273.16 K.

Assertion: Aquatic species are more comfortable in warm waters than cold waters . Reason: K_H values for both N_2 and O_2 decrease with increase of temperature