For the equilibrium at `298 K, N_(2)O_(4)(g) hArr 2NO_(2)(g), G_(N_(2)O_(4))^(ɵ)=100 kJ mol^(-1)` and `G_(NO_(2))^(ɵ)=50 kJ mol^(-1)`. If `5` mol of `N_(2)O_(4)` and `2` moles of `NO_(2)` are taken initially in one litre container than which statement are correct.

For the equilibrium, N_(2) O_(4) hArr 2NO_(2) , (G^(@)N_(2)O_(4))_(298) = 100 kJ/mole and (G^(@) NO_(2))_(298) = 50 kj/mole . When 5 mole / lit of each is taken, the value of Delta G for the reaction.

For the equilibrium, N_(2)O_(4)hArr2NO_(2) , (G_(N_(2)O_(4))^(@))_(298)=100kJ//mol and (G_(NO_(2))^(@))_(298)=50kJ//mol . ( a ) When 5 mol//litre of each is taken, calculate the value of DeltaG for the reaction at 298 K . ( b ) Find the direction of reaction.

At the equilibrium of the reaction , N_(2)O_(4)(g)rArr2NO_(2)(g) , the observed molar mass of N_(2)O_(4) is 77.70 g . The percentage dissociation of N_(2)O_(4) is :-

For the equilibrium reaction: 2H_(2)(g) +O_(2)(g) hArr 2H_(2)O(l) at 298 K DeltaG^(Theta) = - 474.78 kJ mol^(-1) . Calculate log K for it. (R = 8.314 J K^(-1)mol^(-1)) .

For the following reaction, the value of K change with N_(2)(g)+O_(2)(g) lt lt 2NO(g), DeltaH=+180 kJ mol^(-1)

For the reaction, N_(2)O_(4)(g) hArr 2NO_(2)(g) , the concentration of an equilibrium mixture at 298 K is N_(2)O_(4)=4.50xx10^(-2) mol L^(-1) and NO_(2)=1.61xx10^(-2) mol L^(-1) . What is the value of equilibrium constant?

For reaction 2NO(g)hArr N_(2)(g)+O_(2)(g) degree of dissociation of N_(2) and O_(2) is x. Initially 1 mole of NO is taken then number of moles of O_(2) at equilibrium is

Consider the following equilibrium N_(2)O_(4)(g)hArr2NO_(2)(g) Then the select the correct graph , which shows the variation in concentrations of N_(2)O_(4) against concentrations of NO_(2) :

In the equilibrium constant for N_(2)(g) + O_(2)(g)hArr2NO(g) is K, the equilibrium constant for (1)/(2) N_(2)(g) + (1)/(2)O_(2)(g)hArrNO(g) will be:

When N_(2)O_(5) is heated at certain temperature, it dissociates as N_(2)O_(5)(g)hArrN_(2)O_(3)(g)+O_(2)(g),K_(c)=2.5 At the same time N_(2)O_(3) also decomposes as : N_(2)O_(3)(g)hArrN_(2)O(g)+O_(2)(g). "If initially" 4.0 moles of N_(2)O_(5) "are taken in" 1.0 litre flask and alowed to dissociate. Concentration of O_(2) at equilibrium is 2.5 M. "Equilibrium concentratio of " N_(2)O_(5) is :