X, Y and Z react in the `1:1:1` stoichiometric ratio.
The concentration of X, Y and Z we are found to vary with time as shown in the figure below:

If the above equilibrium is established in a `2.0 L` container by taking reactants in sufficient amount then how many moles of components Y must have reacted to establish the equilibrium?

X, Y and Z react in the 1:1:1 stoichiometric ratio. The concentration of X, Y and Z we are found to vary with time as shown in the figure below: Which of the following equilibrium reaction represents the correct variation of concentration with time?

X, Y and Z react in the 1:1:1 stoichiometric ratio. The concentration of X, Y and Z we are found to vary with time as shown in the figure below: The value of the equilibrium constant (K_(c)) for the equilibrium represented the in above sketch will be

The equilibrium concentration of x, y and z are 4, 2 and 2 mol L^(-1) , respectively, at equilibrium of the reaction 2x+y hArr z . The value of K_(c) is ……………..

The initial concentration of X and Y were 2 and 4 mole / L respectively . For the following equilibrium X+2YhArrZ which of the following relationship among equilibrium concentrations of x , y and z is not feasible ?

One mole of X and Y are allowed to react in a 2L container when equilinrium is reached the following reaction occurs 2X+YhArrZ . If the concentration of Z is 0.2M calculate the equilibrium constant for this reaction

For a reversible reaction: X+2Y rarr 2Z , the equilibrium concentrations of X, Y and Z are 0.32, 0.40 and 0.35 moles L^(-1) respectively at 25^(@)C . a. If unitially the system contained only X and Y and then reached the state of equilibrium, what were the initial concentrations of X and Y . b. If at the start only X and Z were present, what were the initial concentrations?

Consider the reaction X(g) hArr Y(g)+Z(g) When the system is at equilibrium at 100^(@) , the concentrations are found to be [X]=0.2 M, [Y]=[Z]=0.4 M a. If the pressure of the container is suddenly halved at 100^(@)C , find equilibrium concentration. b. If the pressure of the container is suddenly doubled at 100^(@)C , find the equilibrium concentration

In the reaction X(g)+Y(g)hArr2Z(g),2 mole of X,1 mole of Y and 1 mole of Z are placed in a 10 litre vessel and allowed to reach equilibrium .If final concentration of Z is 0.2 M , then K_(c) for the given reaction is :

In the reaction X_((g))+ Y_((g)) hArr 2Z_((g)) , 2 moles of X, I mole of Y and I mole of Z are placed in a 10 lit vessel and allowed to reach equilibrium. If final concentration of Z is 0.2 M, then K_(c) . for the given reaction is

For the reaction, x + y harr 2z initially 1 mole of x, 1.5 mole of y & 0.5 mole of z are taken, then at equilibrium 1 mole of z is obtained . If K_eq = X//15 then , find the value of X.