Relate `K_(p) and K_(c)` when `Deltan=0, Deltan=1, Deltan=2.0`

What happens when Deltan_(g)=0,Deltan_(g)=-"ve",Deltan_(g)=+"ve" in a gaseous reaction.

The relation between K_(p) and K_(c) for the following reaction : 2 SO_(2) (g) + O_(2) (g) hArr 2 SO_(3) (g) is -

Establish the relation between K_(p) and K_(c) for the following reactions: aA+bBhArrlL+mM [where the terms have their usual significance].

Write down the relation between K_(p) and K_(c) of the reaction H_(2) (g) + I_(2) (g) hArr 2 HI(g)

What will be the relation between K_(p) and K_(c) for the given equilibrium ? CO(g)+H_(2)O(g)hArrCO_(2)(g)+H_(2)(g) .

Write down the Arrhenius equation relating the rate constant of reaction with temperature , mentioning what the terms indicate. If k_(1) and k_(2) be the rate constant of a reaction at temperature t_(1)^(@)C and t_(2)^(@)C , respectively, find out the relation between k_(1) ,k_(2) and t_(1) and t_(2) . Given that the activation energy (E_(a)) of the reaction remains unchanged within the temperature range mentioned. The rate constant of a reaction at 400K and 500K are 0.02s^(-1) and 0.08s^(-1) respectively . Determine the activation energy (E_(a)) of the reaction.

Find the value of DeltaG^(0) and K_(c) for the following reaction at 298K. NO(g)+(1)/(2)O_(2)(g)hArrNO_(2)(g) Given: standard free energy of formation (DeltaG_(f)^(0)) of NO_(2) and NO are 52.0 and 87.0 kJ*mol^(-1) respectively.

At a given temperature, the reaction, A(g)hArr 2N(g) , is in equilibrium in a closed flask. At the same temperature, the reaction c(g)hArr D(g)+E(g) is in equilibrium in an another closed flask. Values of equilibrium constants of these two reactions are K_(p1) and K_(p2) respectively and the total pressures of the equilibrium mixtures are P_1 and P_2 respectively. If K_(p1) : K_(p2) = 1 : 4 and P_1 : P_2 = 1 : 4 then the ratio of degree of dissociation of A(g) and C(g) are ( assume the degrees of dissociation of both are very small compared to 1)-