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.

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 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.

In the reaction equilibrium N_(2)O_(4) hArr 2NO_(2)(g) When 5 mol of each is taken and the temperature is kept at 298 K , the total pressure was found to be 20 bar. Given : Delta_(f)G_(n_(2)O_(4))^(ɵ)=100 kJ, Delta_(f)G_(NO_(2))^(ɵ)=50 KJ a. Find DeltaG^(ɵ) of the reaction at 298 K . b. Find the direction of the reaction.

In the reaction equilibrium N_(2)O_(4) hArr 2NO_(2)(g) When 5 mol of each is taken and the temperature is kept at 298 K , the total pressure was found to be 20 bar. Given : Delta_(f)G_(n_(2)O_(4))^(ɵ)=100 kJ, Delta_(f)G_(NO_(2))^(ɵ)=50 KJ a. Find DeltaG of the reaction at 298 K . b. Find the direction of the reaction.

For the reaction: N_(2)O_(4)(g) hArr 2NO_(2)(g) (i)" " In a mixture of 5 mol NO_(2) and 5 mol N_(2)O_(4) and pressure of 20 bar. Calculate the value of DeltaG for the reaction. Given DeltaG_(f)^(@) (NO_(2)) = 50 KJ/mol, DeltaG_(f)^(@) ((N_(2)O_(4)) =100 KJ/mol and T=298 K. (ii) Predict the direction in which the reaction will shift, in order to attain equilibrium [Given at T=298 K, 2.303 "RT" = 5.7 KJ/mol.]

For the reaction: N_(2)O_(4)(g) hArr 2NO_(2)(g) (i)" " In a mixture of 5 mol NO_(2) and 5 mol N_(2)O_(4) and pressure of 20 bar. Calculate the value of DeltaG for the reaction. Given DeltaG_(f)^(@) (NO_(2)) = 50 KJ/mol, DeltaG_(f)^(@) ((N_(2)O_(4)) =100 KJ/mol and T=298 K. (ii) Predict the direction in which the reaction will shift, in order to attain equilibrium [Given at T=298 K, 2.303 "RT" = 5.7 KJ/mol.]

For the reaction equilibrium, N_2O_4 (g) hArr 2NO_2 (g) the concentrations of N_2O_4 and NO_2 at equilibrium are 4.8 xx 10^(-2) and 1.2 xx 10 ^(-2) " mol " L^(-1) respectively . The value of K_c for the reaction is

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?

N_(2)O_(4(g))rArr2NO_(2),K_(c)5.7xx10^(-9) at 298 K At equilibrium :-

For the gasesous reaction, 2NO_(2)hArrN_(2)O_(4) , calculate DeltaG^(@) and K_(p) for the reaction at 25^(@)C . Given G_(fN_(2)O_(4))^(@) and G_(fNO_(2))^(@) are 97.82 and 51.30kJ respectively. Also calculate DeltaG^(0) and K_(p) for reverse reaction.