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

K_(c) for the reaction N_(2)O(g)hArr2NO_(2)(g) is 4.63xx10^(-3) at 25^(2)C . a. What is the value of K_(p) at this temperature? b. At 25^(@)C , if the partial pressure of N_(2)O_(4)(g) at equilibrium is 0.2 atm, calculate equilibrium pressure of NO_(2)(g)

The equilibrium partial pressures of CO(g), CO_(2)(g) in the equilibrium reaction CO_(2)(g)+C(s) iff 2CO(g) at 1000 K are 0.66 and 0.15 bar respectively. The equilibrium constant K_(c) are apporximately is

A sample of HI(g) is placed in 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)hArrH_(2)(g)+I_(2)(g)

The following equilibrium constants were determined at 1120k : 2CO_((g)) hArr C_((s)) + CO_(2(g)) , Kp_(I) = 10^(-14) atm^(-1) , CO_((g)0 + Cl_(2(g)) hArr COCl_(2(g)) , Kp_(2) = 6 xx 10^(-3) atm^(-1) What is the equilibrium constant Kc for the following reaction at 1120K: C_((s)) + CO_(2(g)) + 2Cl_(2(g)) hArr 2CO_(2) Cl_((g))

Mass action ratio or reaction quotient Q for a reaction can be calculated using the law of mass action A(g)+B(g) harr C(g) + D(g) Q=([C][D])/([A][B]) . The value of Q decides whether the reaction is at equilibrium or not. At equilibrium, Q = K. For non equilibrium process, Q ne K . When Q gt K , reaction will favour backward direction and when Q lt K , it will favour forward direction. In a reaction mixture containing H_2 , N_2 and NH_3 at partial pressure of 2 atm, and 3 atm respectively, the value of K_p at 725 K is 4.28 xx 10^(-5) atm^(-2) . In which direction the net reaction will go ? N_(2(g)) + 3H_(2(g)) harr 2NH_(3(g))

Steam is passed over hot carbon to attain the equilibrium at 400k. C_(s) + H_(2)O_((g)) hArr CO_((g)) + H(2(g)) . The equilibrium constant k = 1.34 (dimensionless) and the total pressure of the equilibrium mixture is 200 k.pa. Which one is correct when equilibrium is attained

The standard internal energy change during the course of reaction at equilibrium at 300K : 2A_((g)) + B_((g)) hArr A_(2) B_((g)) is : (Given , K_(p) = 10^(-10) atm^(-2) and Delta S^(@) = 5 jK^(-1) )

The equilibrium constant K (in atm) for the reactio is 9 at 7 atm and 300 K, A_(2(g)) hArr B_(2(g)) + C_(2(g)) . calcuate the average molar mass (in gnm/mol) of an equilibrium mixture. Given: Molar mass of A_(2) B_(2) and C_(2) are 70, 49 and 21 gm/mol fespectively.