The equilibrium constant for the following reaction is 10.5 at 500 K .A system at equilibrium has `[CO]=0.250M and [H_(2)]=0.120 M "what is the "[CH_(3)OH]`?
`CO(g)+2H_(2)(g)hArrCH_(3)OH(g)`

Passage: When all the coefficients in a balanced chemical equation are multiplied by a constant factor X the equilibrium constant (originally K) becomes K^J . Similarly, when balanced equations are added together, the equilibrium constant for the combined process is equal to the product of the equilibrium constants for each step. Equilibrium constant of the reversed reaction is numerically equal to the reciprocal of the equilibrium constant of the original equation. Unit of K_p = ("atm")^(Deltan) , Unit of K_c =("mol" L^(-1))^(Deltan) The equilibrium constants for the following reactions at 1400 K are given: 2H_2O_((g)) harr 2H_(2(g))+O_(2(g)) , K_1=2.1 xx 10^(-13) 2CO_(2(g)) harr 2CO_((g))+O_(2(g)) , K_2=1.4 xx 10^(-12) Then the equilibrium constant K for the reaction, H_(2(g))+CO_(2(g)) harr CO_((g)) + H_2O_((g)) is

The equilibrium constant for the following reaction is 1.6xx10^(5) at 1024k H_(2)(g)+Br_(2)(g)hArr2HBr(g) Find the equilibrium pressure of all gases if 10.0 bar of HBr is introdued into a sealed container at 1024K .

At 700K equilibrium constant for the reaction : H_(2)(g) +I_(2)(g)hArr2HI(g) is 54.8 . If 0.5mol^(-1) of HI(g) is present at equilibrium at 700K . What are the concentration of H_(2)(g) and I_(2)(g) assuming that we initially started with HI(g) and allowed it to reach equilibrium at 700K ?

If the equilibrium constant for the reaction, H_(2)(g) +I_(2)(g) hArr 2HI(g) is K What is the equilibrium constant of HI(g) rarr 1/2 H_(2)(g) + 1/2I_(2)(g) ?

The equilibrium constant of the reaction, SO_(2)(g) + 1/2 O_(2)(g) hArr 2SO_(3)(g) is 5 xx 10^(-2)atm . The equilibrium constant of the reaction, 2SO_(3)(g) hArr 2SO_(2)(g) + O_(2)(g)

The equilibrium constant for the reaction: N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g) at 725K is 6.0xx10^(-2) . At equilibrium [H_(2)]=0.25 "mol" L^(-1) and [NO_(3)]=0.06 "mol" L^(-1) Calculate the equilirbium concentration of N_(2) .

A mixture of 1.57 mol of N_(2) , 1.92 mol of H_(2) and 8.13 mol of NH_(3) is introduced into a 20L reaction vessel at 500K . At this temperature, the equilibrium constant, K_(c) for the reaction N_(2)(g)+3H_(2)(g)hArr2NH_(3)(g) is 1.7xx10^(2) . Is the reaction mixture at equilibrium ? If not, what is the direction of the net reaction ?

Passage: When all the coefficients in a balanced chemical equation are multiplied by a constant factor X the equilibrium constant (originally K) becomes K^J . Similarly, when balanced equations are added together, the equilibrium constant for the combined process is equal to the product of the equilibrium constants for each step. Equilibrium constant of the reversed reaction is numerically equal to the reciprocal of the equilibrium constant of the original equation. Unit of K_p = ("atm")^(Deltan) , Unit of K_c =("mol" L^(-1))^(Deltan) Consider the reactions: (i) CO_((g))+H_2O_((g)) harr CO_(2(g))+H_(2(g)) , K_1 (ii) CH_(4(g))+H_2O_((g)) harr CO_((g))+3H_(2(g)) , K_2 (iii) CH_(4(g))+2H_2O_((g)) harr CO_(2(g))+4H_(2(g)) , K_3 Which of the following is correct ?

Write expression for the equilibrium constant, K_(c) , for each of the following reactions: (i) 2NOCl_((g))harr2NO_((g))+Cl_(2(g)) (ii) 2Cu(NO_(3))_(2(s))hArr 2CuO_((s))+4NO_(2(g))+O_(2(g)) (iii) CH_(3)COOC_(2)H_(5(ag))+H_(2)O(I)hArr CH_(3)COOH_((aq))+C_(2)H_(5)OH_((aq)) (iv) Fe_((aq))^(+3)+3OH_((aq))^(-)hArrFe(OH)_(3(S)^(+))