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

Determine K_(p) for the reaction : A(g) + B(s) hArr C(g) + D(g), K_(c) = 49 at 127^(@)C .

For the reactions : C(s) + O_(2) (g) to CO_(2) (g)

The equilibrium constant for the reaction N_(2)(g)+O_(2)(g) hArr 2NO(g) at temperature T is 4xx10^(-4) .The value of K_(c) for the reaction NO(g) hArr 1/2 N_(2)(g)+1/2 O_(2)(g) at the same temperature is

For the reaction A(g) iff B (g), K_(C)=10 B(g) iff C(g), K_(C)=2 C(g) iff D(g), K_(C)=0.01 Calculate K_(C) for the reaction D(g) iff A(g) .

Equilibrium constant, K_(C ) for the reaction N_(2)(g) + 3H_(2)(g) hArr 2NH_(3)(g) at 500 K is 0.061 At a particular time, the analysis shows that composition of the reaction mixture is 3.0 mol L^(-1)N_(2), 2.0 "mol L"^(-1) H_(2) , 0.5 mol L^(-1) NH_(3) . Is the reaction at equilibrium ? If not, in which direction does the reaction tends to proceed to reach equilibirum ?

5 litre vessel contains 2 moles of each of gases A and B at equilibrium. If 1 mole each of A and B are removed. Calculate K_(C) for the reaction A(g) iffB(g)

The equilibrium constant K_(c) for the reaction P_(4)(g)hArr 2P_(2)(g) is 1.4 at 400^(@)C. Suppose that 3 moles of P_(4)(g) and 2 moles of P_(2)(g) are mixed in 2 litre container at 400^(@)C. What is the value of reaction quotient (Q_(c)) ?

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

Calculate the equilibrium constant, K_(C) for the reaction 3Sn^(4+)+2Cr to 3Sn^(2+)+2Ce^(3+) , at 298K given E_(cell)^(@)=0.83V