In the following equilibrium , `N_2O_4(g) hArr 2NO_2(g)`
When 5 moles of each are taken , the temperature is kept at 298 K the total pressure was found to be 20 bar . Given that
`DeltaG_f^@(N_2O_4)=100 KJ`
`DeltaG_f^@(NO_2)=50 kJ`
(i) Find `DeltaG` of the reaction.
(ii) in which direction the equilibrium of reaction will shift ?

(a) In the following equilibrium N_(2)O_(4)(g)hArr2NO_(2)(g) when 5 moles of each are taken, the temperature is kept at 298K the total pressure was found to be 20 bar. Given that DeltaG_(f)^(@)(N_(2)O_(4))=100kJ, DeltaG_(f)^(@)(NO_(2))=50kJ (i) Find DeltaG of the reaction. (ii) The direction of th reaction in which the equilibrium shifts. (b) A graph is plotted for a real gas which follows van der Waals' equation with pV_(m) taken on Y -axis and p on X -axis. Find the intercept of the ine where V_(m) is molar volume.

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 equilibrium reaction 2NO_2(g) hArr N_2O_4(g) + 60.0 kJ the increase in temperature

For the following equilibrium reaction N_(2)O_(4)(g)hArr 2NO_(2)(g) , NO_(2) is 50% of the total volume at a given temperature. Hence, vapour density of the equilibrium mixture is :

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 following reaction at equilibrium 2NO_2(g) harr N_2O_4(g) DeltaH = -58 KJ/mole following change are made then identify in which direction reaction shift