Calculate partial pressure of B at equilibrium in the following equilibrium
`A(s) iff B(g) +2C(g), " " K_(P)=32 atm^(3)`.

A sample of HI (g) is placed in a flask at a pressure of 0.2 atm. At equilibrium the partial pressure of HI (g) is 0.04 atm. What is K_(p) for the given equilibrium ? 2HI(g) hArr H_(2)(g) + I_(2)(g)

Calculate K_(P) for the reaction A(g) iff B(s)+2C(g), K_(C)=0.2 at 305 K.

Find out the value of K_(c) for each of the following equilibrium from the value of K_(p) : 2NOCl(g) hArr 2NO (g) + Cl_(2)(g), K_(p) = 1.8 xx 10^(-2) at 500 K.

What is the effect of increasing pressure on the equilibrium H_(2)(g) + I_(2)(g) hArr 2HI(g) ?

Using Le-Chatelier's principle predict the effect of increasing the pressure on following equilibrium : N_(2)(g) + 3H_(2)(g) hArr 2NH_(3)(g) + Heat

Describe the effect of : removal of CO on the given equilibrium: 2 H_(2) (g) + CO (g) hArr CH_(3)OH

Find out the value of K_(c) for each of the following equilibrium from the value of K_(p) : CaCO_(3)(s) hArr CaO(s) + CO_(2)(g), K_(p) = 167 atm at 1073 K.

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)

What is the effect of increasing pressure on the equilibrium ? 2SO_(2) (g) + O_(2)(g) hArr 2SO_(3)(g)

At a certain temperature , only 50% HI is dissociated at equilibrium in the following reaction: 2HI(g)hArrH_(2)(g)+I_(2)(g) the equilibrium constant for this reaction is: