For the hypothetical reactions, the equilibrium constant (K) values are given
`A harr B, K_1=2.0` `B harr C, K_2=4.0` `C harr D, K_3=3.0`
The equilibrium constant for the reaction `A harr D` is

The following equilibria are given N_2+3H_2 harr 2NH_3 , K_c=K_1 , N_2+O_2 harr 2NO, k_c=K_2 , H_2+1/2 O_2 harr H_2O, K_C = K_3 The equilibrium constant of the reaction. 2NH_3+5/2 O_2 harr 2NO+3H_2O in the terms of K_1,K_2 and K_3 is

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 given reaction is 100. N_(2)(g) + 2O_(2)(g) hArr 2NO_(2)(g) What is the equilibrium constant for the reaction given below? NO_(2)(g) hArr 1/2 N_(2)(g) + O_(2)

If the equilibrium constant for the reaction 2AB hArr A_(2) + B_(2) is 49 what is the value of equilibrium constant for AB hArr 1/2 A_(2) + 1/2 B_(2) ?

Delta G^(0) for the reaction x + y hArr z is -4.606 kcal. The value of equilibrium constant of the reaction at 227^(@)C

The equilibrium constant (K_(C)) for the reaction HA +B hArr BH^(+) + A is 100. If the rate constant for the forward reaction is 10^(5) , rate constant for the reverse reaction is

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 two reactions: XeF_(6(g))+H_(2)O_((g)) harr XeOF_(4(g))+2HF_((g)), K_(1)" "XeO_(4(g))+XeF_(6(g)) harr XeOF_(4(g))+XeO_(3)F_(2(g)), K_(2) Then the equilibrium constant for the following reaction will be XeO_(4(g))+2HF_((g)) harr XeO_(3)F_(2(g))+H_(2)O_((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

Which of the following are correct about the reaction A + 2B hArr C + D

As per the graph what is K_c of A harr nB