For a gaseous reaction
`aA(g)+bB(g)hArrcC(g)+dD(g)`
equilibrium constants `K_(c),K_(p)` and `K_(x)` are represented by the following reation
`K_(c)=([C]^(c)[D]^(d))/([A]^(a)[B]^(b)),K_(p)=(Pc^(c).P_(D)^(d))/P_(A)^(a)` and `Kx=(x_(C)^(c).x_(D)^(d))/(x_(A)^(a).x_(B)^(b)`
where `[A]` represents molar concentrationof `A,p_(A)` represents partial pressure of A and P represents total pressure, `x_(A)` represents mole fraction of A
For the reaction `SO_(2)Cl_(2)(g)hArrSO_(2)(g)+Cl_(2)(g),K_(p)gtK_(x)` is obtained at :

For a gaseous reaction aA(g)+bB(g)hArrcC(g)+dD(g) equilibrium constants K_(c),K_(p) and K_(x) are represented by the following reation K_(c)=([C]^(c)[D]^(d))/([A]^(a)[B]^(b)),K_(p)=(Pc^(c).P_(D)^(d))/P_(A)^(a) and Kx=(x_(C)^(c).x_(D)^(d))/(x_(A)^(a).x_(B)^(b) where [A] represents molar concentrationof A,p_(A) represents partial pressure of A and P represents total pressure, x_(A) represents mole fraction of For the following equilibrium relation betwen K_(c) and K_(c) (in terms of mole fraction) is PCl_(3)(g)+Cl_(2)(g)hArrPCl_(5)(g)

For the reaction CO(g)+Cl_(2)(g)hArrCOCl_(2)(g) the value of (K_(c)/(K_(P))) is equal to :

For the reaction H_(2)(g)+I_(2)(g)hArr2HI(g) the equilibrium constant K_(p) changes with

What is the unit of K_(p) for the reaction ? CS_(2)(g)+4H_(4)(g)hArrCH_(4)(g)+2H_(2)S(g)

The equilibrium constant K_(p) for the following rection at 191^(@)C is 1.24. what is K_(c) ? B(s)+(3)/(2)F_(2)(g)hArr(g)

For the reaction 2NO_(2)(g)+(1)/(2)O_(2)(g)hArrN_(2)O_(5)(g) if the equilibrium constant is K_(p) , then the equilibrium constant for the reaction 2N_(2)O_(5)(g)hArr4NO_(2)(g)+O_(2)(g) would be :

For the equilibrium SO_(2)Cl_(2)(g)hArrSO_(2)(g)+Cl_(2)(g) , what is the temperature at which (K_(p)(atm))/(K_(c)(M))=3 ?

If a, b,c are in G.P., prove that the following are also in G.P. : a^(2),b^(2),c^(2) .