Following reaction occurs at `25^(@)` :
`2NO(g, 1xx10^(-5)atm) + CI_(2)(g, 1 xx 10^(-2)atm)hArr 2NOCI(g,1 xx 10^(-2)atm)`
Calculate `DeltaG^(@) [R = 8 J//"mole" K]`

Following reaction occurs at 25^(@)C 2NO(g,1xx10^(-5)atm)+Cl_(2)(g,1xx10^(-2)atm) 2NOCl(g,1xx10^(-2)atm)DeltaG^(@) is R=8J//"mole"K

Following reaction in equilibrium at 25^(@)C : 2NO(g,1 xx 10^(-5) "atm")+Cl_2(g,1 xx 10^(-2)"atm") harr 2NOCl(g, 1 xx 10^(-2) "atm") DeltaG^@ is

Given equilibrium constants for the following reaction at 1200^(@)C C(g)+CO_(2)(g)hArr 2CO(g), K_(p_(1))=1.47xx10^(3) CO(g)+1//2O_(2)(g)hArr COCl_(2)(g), K_(P_(2))=2xx10^(6) Calculate K_(P) for the reaction : C(g)+CO_(2)+O_(2)(g)hArr 2COCl_(2)(g)

For the equilibrium, PCI_(5)(g) hArr PCI_(3)(g) +CI_(2)(g) at 25^(@)C K_(c) =1.8 xx 10^(-7) Calculate DeltaG^(Theta) for the reaction (R = 8.314 J K^(-1) mol^(-1)) .

For the equilibrium, PCI_(5)(g) hArr PCI_(3)(g) +CI_(2)(g) at 25^(@)C K_(c) =1.8 xx 10^(-7) Calculate DeltaG^(Theta) for the reaction (R = 8.314 J K^(-1) mol^(-1)) .

At 800 K in a sealed vessel for the equilibrium N_(2)(g) + O_(2) (g) hArr 2NO(g), the equilibrium concentrations of N_(2) (g), O_(2)(g) and NO(g) are respectively 0.36xx10^(-3) M, 4.41 xx 10^(-3) M and 1.4 xx 10^(-3) M. Calculate the value of K_(c) for the reaction NO(g) hArr 1//2 N_(2)(g) +1//2 O_(2) (g) at 800 K is :

The relation K_(p) " and " K_(c) for the reaction: 2NO (g) + CI_(2) (g) hArr 2NOCI(g) " is":