Question #e8dce
1 Answer
Explanation:
You know that iron(II) oxide-hydroxide is insoluble in water, which implies that a dissociation equilibrium is established in aqueous solution between the undissolved solid and the solvated ions.
"Fe"("OH")_ (3(s)) rightleftharpoons "Fe"_ ((aq))^(3+) + 3"OH"_( (aq))^(-)Fe(OH)3(s)⇌Fe3+(aq)+3OH−(aq)
By definition, the solubility product constant,
K_(sp) = ["Fe"^(3+)] * ["OH"^(-)]^3Ksp=[Fe3+]⋅[OH−]3
Now, in order for precipitation to occur, you need to have
K_(sp) <= ["Fe"^(3+)] * ["OH"^(-)]^3" "" "color(darkorange)(("*"))Ksp≤[Fe3+]⋅[OH−]3 (*)
As you know, an aqueous solution at room temperature has
color(blue)(ul(color(black)("pOH" = 14 - "pH")))
Since you know that
color(blue)(ul(color(black)("pOH" = - log(["OH"^(-)]))))
you can say that
["OH"^(-)] = 10^(-"pOH")
which is equivalent to
["OH"^(-)] = 10^(-(14 - "pH"))
Plug in the value you have for the
["OH"^(-)] = 10^(-(14 - 3.48))
["OH"^(-)] = 10^(-10.52)
Next, rearrange equation
["Fe"^(3+)] >= K_(sp)/(["OH"^(-)]^3)
Plug in your values to find
["Fe"^(3+)] >= (2.79 * 10^(-39))/(10^(-10.52))^3
["Fe"^(3+)] >= (2.79 * 10^(-39))/( (10^(-10))^3 * (10^(-0.52))^3)
["Fe"^(3+)] >= 2.79 * 10^(1.56) * 10^(-39) * 10^(30)
Therefore, you can say that you need
color(darkgreen)(ul(color(black)(["Fe"^(3+)] >= 1.0 * 10^(-7)color(white)(.)"M")))
The answer is rounded to two sig figs, the number of decimal places you have for the
