Question #964ef
1 Answer
Here's what I got.
Explanation:
You know you start with
#["A"] = "0.650 M"# #["B"] = "1.15 M"# #["C"] = "0.500 M"#
and that, at equilibrium, the reaction vessel contains
#["A"] = "0.530 M"# #["C"] = "0.620 M"#
Now, notice that the concentration of
#"0.530 M " - " 0.650 M" = -"0.120 M"# The minus sign tells you that the concentration of
#"A"# decreased by#"0.120 M"# .
By comparison, the concentration of
#"0.520 M " - " 0.620 M " - " 0.500 M" = "0.120 M"#
This is consistent with the fact that the reaction proceeded in the forward direction, i.e. the forward reaction was favored. This means that you can represent the reaction as
#"A"_ ((aq)) + color(red)(2)"B"_ ((aq)) -> "C"_ ((aq))#
You can also say that because the forward reaction is favored, the equilibrium constant must come out to be
As you can see, for every
So if the reaction consumed
#color(red)(2) * "0.120 M" = "0.240 M"#
of reactant
#["B"] = "1.15 M " - " 0.240 M" = "0.910 M"#
By definition, the equilibrium constant for this reaction will take the form
#K_c = (["C"])/(["A"] * ["B"]^color(red)(2))#
Now all you have to do is plug in the equilibrium concentrations of the chemical species that take part in the reaction. Since all three chemical species are in the aqueous state, they will be included in the expression of
For the sake of simplicity, I'll leave the answer without added units!
#K_c = (0.620)/(0.530 * (0.910)^color(red)(2)) = color(darkgreen)(ul(color(black)(1.41)))#
I'll leave the answer rounded to three sig figs, but keep in mind that you should have
#["B"] = "1.15 M " - " 0.120 M" = "0.91 M"#
The equilibrium concentration of
This would make
#K_c = (0.620)/(0.530 * (0.91)^color(red)(2)) = 1.4#
As predicted, the value of the equilibrium constant is indeed
