For the reaction at 298K: `A_((g)) +B_((g)) hArr C_((g)) + D_((g)) Delta H^(@) + `29.8kcal and `Delta S^(@) = 100cal K^(-1)`. Find the value of equilibrium constant.

For the reaction at 300 K A_((g)) harr V_((g)) + S_((g) . Delta_(t) H^(@) = - 30 "KJ/mol" Delta_(t)S^(@) = - 0.1 K.J. K^(-1)."mole"^(-1) What Is the value of equilibrium constant ?

The gascous reaction A_((g)) + B_((g)) hArr 2C_((g)) + D_((g)) + q kJ is most favoured at :

For the reaction CO_((g)) + Cl_(2(g)) hArr COCl_(2(g)). The K_(p)//K_(c) is equal to

For the reaction CO_((g))+CI_(2(g)) harr COCI_(2(g)) . The K_p // K_c is equal to

For the reaction A_((g))+B_((g)) harr C_((g))+D_((g)) K is 0.63 at 700^(@)C and 1.66 at 1000^(@)C . Then DeltaH^(@) is x KCal. What is x?

The yield of product in the reaction 2A_((g)) + B_((g)) hArr 2C_((g)) + Q K J would be lower at :

At a certain temperature the equilibrium constant K_c is 0.25 for the reaction A_(2(g))+B_(2(g)) harr C_(2(g))+D_(2(g)) If we take 1 mole of each of the four gases in a 10 litre container, what would be equilibrium concentration of A_(2(g)) ?

For the reaction X_(2)O_(4(l)) rarr 2XO_(2(g)), Delta U= 2.1 "kcal", Delta S= 20 "cal " K^(-1) at 300K, Hence Delta G is