For `N_(2(g)` at 1 atm `to N_(2)(g)` at 0.5 atm, What would be the change in entropy ?

The equilibrium constant K_(P) for the reaction N_(2)O_(4)(g) hArr 2NO_(2)(g) is 4.5 atm . What would be the average molar mass (in g//mol ) of an equilibrium mixture at a total pressure of 2 atm of N_(2)O_(4) and NO_(2) formed by the dissociation of pure N_(2)O_(4) ?

For the transformation, H_(2)O(l,1 atm) "to H_(2)O (g,1atm), DeltaH_(vap)=40.668kJmol^(-) The change in entropy (JK^(-)mol^(-)) is:

A container with a volume of 20.0 L holds N_(2)(g) and H_(2)O(l) at 300 K and 1.0 atm. The liquid water is then decomposed completely into H_(2)(g) and O_(2)(g) by any means, at constant temperature. If the final pressure becomes 1.86 atm, what was the mass of water (in gm) present initially. Neglect the initial volume of water. [Given : Vapour pressure of water at 300 K = 0.04 atm, R = 0.08 L-atm/K-mol]

For the decomposition reaction: N_(2)O_(4(g))rarr 2NO_(2(g)) , the initial pressure of N_(2)O_(4) falls from 0.46 atm to 0.28 atm in 30 minute. What is the rate of appearance of NO_(2) ?

For the reaction , O_2(g)+2F_2(g)to2OF_2(g),K_p=4.1 If P_(O_2)(g)=0.116 atm and P_(F_2)(g)=0.0461 atm at equilibrium , what is the pressure of OF_2(g) ?