Calculate pCu2+ at each of the following points in the titration of 50.00 mL of 0.001...
Calculate pCu2+ at each of the following points in the titration of 50.00 mL of 0.001 00 M Cu2+ with 0.00100 M EDTA at pH 11.00 in a solution with [NH3] fixed at 1.00 M:
(a) 0 mL (c) 45.00 mL (e) 55.00 mL (b) 1.00 mL (d) 50.00 mL
Please show all steps to solution; thank you.
Homework Answers
EDTA is a tetrabasic acid that has six potential sites
for bonding with a metal ion, four carboxyl groups
and the two amino groups , each of the latter with
unshared pair of electrons. Thus EDTA is a
hexadentate ligand.
The dissociation constants for the acidic groups in
EDTA are K1= 1.02x10-2, K2= 2.14x10-3,
K3= 6.92x10-7 and K4 = 5.50x10-11.
%uF06E The various EDTA species are often
abbreviated as H4Y, H3Y-, H2Y2-, HY3- and Y4-.
The fully unprotonated form Y4- is dominant only in very
basic solutions (pH>10).here pH=11
Cu2+ can also be titrated in alkaline medium
(pH 10) using ammoniacal buffer and Eriochrome
black T as indicator.
EDTA is not a selective reagent (G.R.) as it can complex
with almost all metal ions (cations)except alkali metals in a
ratio 1:1 regardless of the charge on the cation.
e.g. Mg2+ + H2Y2- -------- MgY2-
Al3+ + H2Y2- ------------- AlY-
so for Cu2+ it reacts with 1:2 ratio
EDTA is a tetrabasic acid that has six potential sites
for bonding with a metal ion, four carboxyl groups
and the two amino groups , each of the latter with
unshared pair of electrons. Thus EDTA is a
hexadentate ligand.
The dissociation constants for the acidic groups in
EDTA are K1= 1.02x10-2, K2= 2.14x10-3,
K3= 6.92x10-7 and K4 = 5.50x10-11.
%uF06E The various EDTA species are often
abbreviated as H4Y, H3Y-, H2Y2-, HY3- and Y4-.
The fully unprotonated form Y4- is dominant only in very
basic solutions (pH>10).here pH=11
Cu2+ can also be titrated in alkaline medium
(pH 10) using ammoniacal buffer and Eriochrome
black T as indicator.
EDTA is not a selective reagent (G.R.) as it can complex
with almost all metal ions (cations)except alkali metals in a
ratio 1:1 regardless of the charge on the cation.
e.g. Mg2+ + H2Y2- -------- MgY2-
Al3+ + H2Y2- ------------- AlY-
so for Cu2+ it reacts with 1:2 ratio
Add Answer to:
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pCu2+
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