Answer:
[tex][COCl_2]_{eq}=0.424M[/tex]
[tex][Cl_2]_{eq}=0.074M[/tex]
[tex][CO]_{eq}=0.074M[/tex]
Explanation:
Hello,
In this case, one could solve the problem by stating the law of mass action for the undergoing chemical reaction which is:
[tex]CO(g)+ Cl_2(g)\rightarrow COCl_2(g)[/tex]
As shown below:
[tex]Keq=\frac{[COCl_2]}{[CO][Cl_2]}=77.5[/tex]
Now, the initial concentration of carbon monoxide equals that of chlorine which results:
[tex][CO]_0=[Cl_2]_0=\frac{0.498mol}{1L}=0.498M[/tex]
Next, as the change [tex]x[/tex] is introduced due to the chemical reaction, considering the stoichiometry, the law of mass action turns out:
[tex]Keq=77.5=\frac{x}{(0.498M-x)(0.498M-x)}[/tex]
Solving for [tex]x[/tex] by using the quadratic equation one obtains:
[tex]x_1=0.424M\\x_2=0.585M[/tex]
Therefore, the feasible result is 0.424M as the other one will lead to negative concentrations at the equilibrium. Thus, the equilibrium concentrations are:
[tex][COCl_2]_{eq}=x=0.424M[/tex]
[tex][Cl_2]_{eq}=0.498M-x=0.498M-0.424M=0.074M[/tex]
[tex][CO]_{eq}=0.498M-x=0.498M-0.424M=0.074M[/tex]
Best regards.
