For the reaction 2X+Y+Z`to X_2 YZ`, the rate equation is : Rate `=k [X] [Y]^2` with k `= 3.0 xx 10^(-6) mol^(-2) L^(2) s^(-)` If[X]=0.1 mol `L^(-)` ,[Y]=0.2 mol L-and [Z]=0.7 mol` L^(-)`, determine
the rate after 0.02 mole of X has been reacted.

For the reaction 2X+Y+Z to X_2 YZ , the rate equation is : Rate =k [X] [Y]^2 with k = 3.0 xx 10^(-6) mol^(-2) L^(2) s^(-) If[X]=0.1 mol L^(-) ,[Y]=0.2 mol L-and [Z]=0.7 mol L^(-) , determine the initial rate of reaction.

For the reaction : 2A+B rarr A_(2)B the rate =k[A][B]^(2) with k=2.0xx10^(-6)mol^(-2)L^(2)s^(-1) . Calculate the initial rate of the reaction when [A]=0.1 mol L^(-),[B]=0.2 mol L^(-1) . Calculate the rate of reaction after [A] is reduced to 0.06 mol L^(-1) .

For the reaction : 2A + B to A_2B , the rate = K[A][B]^2 with K = 2.0 xx 10^(-6) mol^(-1) lit^(2) sec^(-1) . Initial concentration of A and B are 0.2 mol/lt and 0.4 mol/lit respectively. Calculate the rate of reaction after [A] is reduced to 0.12 mol/lit

For a first order for the reaction A rarr products : the rate of reaction at [A]=0.2 M is 1.0 xx 10^(-3) mol L^(-1)s^(-1) . The reaction will occur to 75% completion in .

Identify the reaction order from each of the following rate : k=2.3 xx 10^5 L mol^(-1) s^(-1)

In the system X+2YhArrZ , the equilibrium concentration are, [X]=0.06" mol L"^(-1),[Y]=0.12" mol L"^(-1) , [Z]=0.216" mol L"^(-1) . Find the equilibrium constant of the reaction.