For given two equilibria attained in a container which are correct if degree of dissociation of A and A' are `alpha` and `alpha'`.
`A(s) hArr 2B(g)+C(g), K_(p_(1))=8xx10^(-2)`
`A'(s) hArr 2B(g)+D(g), K_(P_(2))=2xx10^(-2)`

The degree of dissociation of SO_(3) is alpha at equilibrium pressure P_(0) . K_(P) for 2SO_(3)(g)hArr2SO_(2)(g)+O_(2)(g) is

One "mole" of NH_(4)HS(s) was allowed to decompose in a 1-L container at 200^(@)C . It decomposes reversibly to NH_(3)(g) and H_(2)S(g). NH_(3)(g) further undergoes decomposition to form N_(2)(g) and H_(2)(g) . Finally, when equilibrium was set up, the ratio between the number of moles of NH_(3)(g) and H_(2)(g) was found to be 3 . NH_(4)HS(s) hArr NH_(3)(g)+H_(2)S(g), K_(c)=8.91xx10^(-2) M^(2) 2NH_(3)(g) hArr N_(2)(g)+3H_(2)(g), K_(c)=3xx10^(-4) M^(2) Answer the following: To attain equilibrium, how much % by weight of folid NH_(4)HS got dissociated?

The degree of dissociation alpha of the reaction" N_(2)O_(4(g))hArr 2NO_(2(g)) can be related to K_(p) as:

Predict which of the following reactions will have appreciable concentration of rectants and products: a. Cl_(2)(g) hArr 2Cl(g), K_(c)=5xx10^(-39) b. Cl_(2)(g)+2NO(g) hArr 2NOCl(g), K_(c)=3.7xx10^(8) c. Cl_(2)(g)+2NO_(2)(g) hArr 2NO_(2)Cl(g), K_(c)=1.8

Find out the value of K_(c ) for each of the following equilibrium from the value of K_(p) : a. 2NOCl(g) hArr 2NO(g)+Cl_(2)(g), K_(p)=1.8xx10^(-2) at 500 K b. CaCO_(3)(s) hArr CaO(s)+CO_(2)(g), K_(p)=167 at 1073 K

Find out the value of K_(c ) for each of the following equilibrium from the value of K_(p) : a. 2NOCl(g) hArr 2NO(g)+Cl_(2)(g), K_(p)=1.8xx10^(-2) at 500 K b. CaCO_(3)(s) hArr CaO(s)+CO_(2)(g), K_(p)=167 at 1073 K

Ammonium sulphide and ammonium selenide on heating dissociates as (NH_4)S(s) hArr 2NH_(3)(g) + H_(2)S(g) , k_(p1) = 9 xx 10^(-3) atm^(3) (NH_4)_(2) Se(s) hArr 2NH_(3)(g) + H_(2)Se(g), K_(p2) = 4.5 xx 10^(-3) atm^(3) . The total pressure over the solid mixture at equilibrium is

The equilibrium constant of the following reactions at 400 K are given: 2H_(2)O(g) hArr 2H_(2)(g)+O_(2)(g), K_(1)=3.0xx10^(-13) 2CO_(2)(g) hArr 2CO(g)+O_(2)(g), K_(2)=2xx10^(-12) Then, the equilibrium constant K for the reaction H_(2)(g)+CO_(2)(g) hArr CO(g)+H_(2)O(g) is

Calculate the partial pressure of carbon monoxide from the following data’s CaCO_(3)(s) overset(Delta)to CaO(s) + CO_(2)(g), K_(p) = 8 xx 10^(-2) CO_(2)(g) + C(s) rarr 2CO(g), K_(p) = 2

Arrange the following in order of increasing tendency of the forward reactions to proceed towards completion at 298 K and one atmospheric pressure : a. H_(2)O(g)hArrH_(2)O(l), K_(c)=782 b. F_(2)(g)hArr2F(g), K_(c)=4.9xx10^(-21) c. C_("graphite")+O_(2)(g)hArrCO_(2)(g), K_(c)=1.3xx10^(69) d. N_(2)O_(4)(g)hArr2NO_(2)(g), K_(c)=4.6xx10^(-3) e. H_(2)(g)+C_(2)H_(4)(g)hArrC_(2)H_(6)(g), K_(c)=9.8xx10^(18)