What is the concentration of ferrous ion?

A solution is prepared by mixing 75 ml of 0.030 M # FeSO_4# with 125 ml of 0.20 M KCN?The stability constant for the complex# [Fe(CN)_6]^-4# is# 1* 10^24#.[Given:#(0.0575)^6#=#3.62*10^-8#].

1 Answer
Jan 10, 2018

I got #["Fe"^(2+)] = 3.2 xx 10^(-19) "M"#.


Well, the reaction is:

#"FeSO"_4(aq) + 6"KCN"(aq) -> "K"_4["Fe"("CN")_6] (aq) + "K"_2"SO"_4(aq)#

For simplicity, we include only the complexation participants:

#"Fe"^(2+)(aq) + 6"CN"^(-)(aq) -> ["Fe"("CN")_6]^(4-)(aq)#

The concentration of iron at the start of the reaction is

#"0.030 M" xx "75 mL"/"75 + 125 mL" = "0.0113 M"#,

due to dilution by mixing.

The concentration of cyanide at the start of the reaction is

#"0.20 M" xx "125 mL"/"75 + 125 mL" = "0.125 M"#,

again due to dilution by mixing.

Therefore, we construct the ICE table using molar concentrations:

#"Fe"^(2+)(aq) " "+" " 6"CN"^(-)(aq) -> ["Fe"("CN")_6]^(4-)(aq)#

#"I"" "0.0113" "" "" "" "0.125" "" "" "" "" "0#
#"C"" "-x" "" "" "" "" "-6x" "" "" "" "+x#
#"E"" "0.0113-x" "" "0.125-6x" "" "" "x#

The equilibrium formation of the complex is then given by:

#K_f = 1 xx 10^24 = ([["Fe"("CN")_6]^(4-)])/(["Fe"^(2+)]["CN"^(-)]^6)#

#= x/((0.0113 - x)(0.125 - 6x)^6)#

Since #K_f# is so large, we approximate that #x ~~ 0.0113#, and notice that iron is the limiting reactant. For the purposes of maximizing accuracy, consider the following solving method.

#ln K_f = ln(10^24) = 24ln10#

#= ln[x/((0.0113 - x)(0.125 - 6x)^6)]#

#= lnx - ln(0.0113 - x) - 6ln(0.125 - 6x)#

Now, we can plug in #x = 0.0113# EXCEPT for where we would get #ln -> -oo#. This gives us:

#24ln10 = ln(0.0113) - ln(0.0113 - x) - 6ln(0.125 - 6(0.0113))#

Evaluate the right-hand side to get:

#24ln10 = -4.4830 - ln(0.0113 - x) - 6ln(0.0572)#

If you notice, this would be where that hint came from. Without the #ln#, we would have gotten that #(0.0575)^6 = 3.62 xx 10^(-8)#, since #lna^c = clna#. We proceed to get:

#24ln 10 = -4.4830 - ln(0.0113 - x) + 17.1672#

#= 12.6842 - ln(0.0113 - x)#

Solving for #ln(0.0113 - x)#, we obtain:

#ln(0.0113 - x) = 12.6842 - 24ln10#

#= -42.5778#

As a result,

#color(blue)(["Fe"^(2+)]) = 0.0113 - x#

#= e^(-42.5778)#

#= color(blue)ul(3.2 xx 10^(-19) "M")# to two significant figures.

And just to verify that this is correct... #x = 0.0113 - e^(-42.5778)#, and so we do indeed get #K_f# back:

#K_f = (0.0113 - e^(-42.5778))/((0.0113 - 0.0113 + e^(-42.5778))(0.125 - 6(0.0113 - e^(-42.5778)))^6)#

#~~ (0.0113)/(e^(-42.5778)(0.125 - 6(0.0113))^6)#

#= ul(1.0_(0001349) xx 10^24) = 1 xx 10^24# #color(blue)(sqrt"")#

where the subscripts indicate digits past the last significant figure.