For an isomerization reaction D `harr `L expression for equilibrium constant is given by R =8.3J `K^(-1)``mol^(-1)`
ln K = 4.814 - `(2062.65)/(T(K)` Enthalpy of the reaction `(Delta H^(@))` at `25^(@)C` is

For an isomerisation reaction, A hArr B , the temperature dependence of equilibrium constant is given by Log_0K=4.0 -(2000)/T Find the value of DeltaS^0 at 300 k in cal.

For reaction 2A+B hArr 2C, K=x Equilibrium constant for C hArr A+1//2 B will be

The temperature dependence of equilibrium constant of a reaction is given by In K_(eq) = 4.8 -(2059)/(T) . Find Delta_(r)G^(Theta), Delta_(r)H^(Theta), Delta_(r)S^(Theta) .

Variation of equilibrium constan K with temperature is given by van't Hoff equation InK=(Delta_(r)S^(@))/R-(Delta_(r)H^(@))/(RT) for this equation, (Delta_(r)H^(@)) can be evaluated if equilibrium constans K_(1) and K_(2) at two temperature T_(1) and T_(2) are known. log(K_(2)/K_(1))=(Delta_(r)H^(@))/(2.303R)[1/T_(1)-1/T_(2)] For an isomerization X(g)hArrY(g) the temperature dependency of equilibrium cohnstant is given by : lnK=2-(1000)/T The value of Delta_(r)S^(@) at 300 K is :

The equilibrium constant for a reaction is 10 . What will be the value of DeltaG^(Θ) ? R=8.314 J K^(-1) mol^(-1), T=300 K .

For the hypothetic reaction, the equilibrium constant (K) values are given A hArr B,K_(1)=2.0 B hArr C, K_(2)=4.0 ChArr D, K_(3) =3.0 The equilibrium constant for the reaction A hArr D is