For the system `A(g)+2B(g) hArr C(g)` the equilibrium concentration is
`A=0.06 mol L^(-1), B=0.12 mol L^(-1)`
`C=0.216 mol L^(-1)` The `K_(eq)` for the reaction is

For the system A(g)+2B(g)hArr C(g) , the equilibrium concentration is A="0.06 mol L"^(-1), B="0.12 mol L"^(-1), C="0.216 mol L"^(-1) . The equilibrium cosntant K_(C) for the reaction is

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.

For a system, a+2BhArrC , the equilibrium comcentrations are [A]=0.06, [B]=0.12 , and [C]=0.216 . The K_(c ) for the reaction is

In the reaction, A + B hArr2C , at equilibrium, the concentration of A and B is 0.20 mol L^(-1) each and that of C was found to be 0.60 mol L^(-1) . The equilibrium constant of the reaction is

For the following reaction: 2A + B +C rarr A_(2)B + C The rate law has been determined to be Rate = k[A][B]^(2) with k = 2.0 xx 10^(-6) mol^(-2) L^(2) s^(-1) For this reaction, determine the initial rate of the reaction with [A] = 0.1 mol L^(-1), [B] = 0.2 mol L^(-1), C = 0.8 mo, L^(-1) . Determine the rate after 0.04 mol L^(-1) of A has reacted.