EDTA Titration EDTA = Ethylenediaminetetraacetic acid

Slides:



Advertisements
Similar presentations
Complex Ion Equilibria
Advertisements

Complexometric Titrations(1)
Complexometric Titrations
EDTA Titrations. Chelation in Biochemistry Chelating ligands can form complex ions with metals through multiple ligands. This is important in many areas,
Section 8 Complex-Formation Titrations. Complex-Formation Titrations General Principles Most metal ions form coordination compounds with electron-pair.
213 PHC 8 th lecture (1) Gary D. Christian, Analytical Chemistry, 6 th edition 1.
EDTA Titrations Introduction 1.) Metal Chelate Complexes
CHAPTER 15: APPLICATIONS OF AQUEOUS EQUILIBRIA Dr. Aimée Tomlinson Chem 1212.
Complexation and EDTA Chemistry 321, Summer 2014.
Chapter 13 EDTA Titrations EthyleneDiamineTetraAcetic acid.
Lecture 20 10/19/05.
Copyright McGraw-Hill Chapter 17 Acid-Base Equilibria and Solubility Equilibria Insert picture from First page of chapter.
CHEMISTRY ANALYTICAL CHEMISTRY Fall
Solubility Equilibrium In saturated solutions dynamic equilibrium exists between undissolved solids and ionic species in solutions Solids continue to dissolve.
Ch. 16: Ionic Equilibria Buffer Solution An acid/base equilibrium system that is capable of maintaining a relatively constant pH even if a small amount.
Redox Titrations Introduction 1.) Redox Titration
Chapter 16: Applications of Aqueous Equilibria Renee Y. Becker Valencia Community College 1.
ANALYTICAL CHEMISTRY CHEM 3811 CHAPTER 13
1 Indicators The indicator is usually a weaker chelate forming ligand. The indicator has a color when free in solution and has a clearly different color.
Chapter 13 EDTA Titrations EthyleneDiamineTetraAcetic acid.
Complexation Titrations: Taking Advantage of Complexing Agents
Types of chemistry Although any type of chemical reaction may be used for titrimetric analysis, the most often used fall under the categories of: Bronsted.
Complexometric titrations
Complexometric Reactions and Titrations
Chapter 11 EDTA Titrations
1 Selective Precipitation  a solution containing several different cations can often be separated by addition of a reagent that will form an insoluble.
Chapter 7 Let the Titrations Begin. Titration n Titration –A procedure in which one substance (titrant) is carefully added to another (analyte) until.
Buffers, Titrations, and Aqueous Equilibria. Common Ion Effect The shift in equilibrium that occurs because of the addition of an ion already involved.
Chem. 31 – 3/4 Lecture. Announcements I Exam 1 –Still Grading –Key Posted Next Lab Report Due: Cl lab report –Due next Wednesday –Must turn in in Excel.
COMPLEXOMETRIC REACTIONS AND TITRATIONS
Chapter 13 EDTA Titrations EthyleneDiamineTetraAcetic acid.
What happens to the absorbed energy?. Energy soso s1s1 t1t1.
LECTURE 3 CHAPTER 5: CLASSICAL METHODS OF ANALYTICAL CHEMISTRY: TITRIMETRIC METHODS OF ANALYSIS CO4: ABILITY TO DIFFERENTIATE VARIOUS USED OF COMPLEXATION,
Titration Titration is the quantitative measurement of an analyte (the substance whose quantity or concentration is to be determined) in solution by completely.
Chapter 17 Additional Aspects of Aqueous Equilibria Subhash Goel South GA State College Douglas, GA © 2012 Pearson Education, Inc.
Chapter 14 Equilibria in Acid-Base Solutions. Buffers: Solutions of a weak conjugate acid-base pair. They are particularly resistant to pH changes, even.
1 Titration Curve of a Weak Base with a Strong Acid.
Chapter 13 EDTA Titrations Lewis acid-base concept Lewis acid :electron pair acceptor metal Lewis base : electron pair donor ligand coordinate covalent.
Prentice Hall © 2003Chapter 17 Chapter 17 Additional Aspects of Aqueous Equilibria.
Complexometric Determination of Calcium in Milk
Complexation Reactions and Titrations Dr. Mohammad Khanfar.
Acid-Base Titartions, Cont… Complexometric Reactions
Chapter 9 Complexation and Precipitation Titrations.
Complex Ion Equilibria and Solubility A complex ion can increase the solubility of a salt. Ag + (aq) + 2 NH 3 (aq) Ag(NH 3 ) 2 + (aq) K f = [Ag(NH.
Chapter 13 “EDTA” Titrations It’s a Complex World Out There.
ERT207 Analytical Chemistry Complexometric Titration
Prentice Hall © 2003Chapter 17 Chapter 17 Additional Aspects of Aqueous Equilibria.
EDTA EthyleneDiamineTetraacetic Acid, a compound that forms strong 1:1 complexes with most metal ions. EDTA is a hexaprotic system, designated H 6 Y 2+.
Additional Aspects of Aqueous Equilibria. Roundtable problems P.757: 3, 6, 12, 14, 18, 24, 30, 38, 44, 50, 54, 56, 58, 64, 68, 70, 72, 103.
Chapter 15 Applying equilibrium. The Common Ion Effect l When the salt with the anion of a weak acid is added to that acid, l It reverses the dissociation.
7 장 적정 Stirring bar One method in volumetric analysis is titration In titration: - substance to be analysed is known as the analyte - the solution added.
ERT207 Analytical Chemistry Complexometric Titration Pn Syazni Zainul Kamal PPK Bioproses.
LECTURE 2 Titration method ass. prof. Ye. B. Dmukhalska.
Common Ion Effect, Buffers, and Titration March 4/6, 2015.
Chapter 17 Complexation and Precipitation Reactions and Titrations 1/57.
Chapter 17 Complexation and Precipitation Reactions and Titrations.
Complexometric Titration
Ch. 17 Complexation reactions and titrations A. The formation of complexes Most metal ion : react with electron-donor species to form coordination compounds.
Experiments in Analytical Chemistry -EDTA determination of Ca and Mg in water.
Chapter 11 EDTA Titrations
Titration & pH curves [17.3].
Complexation and Precipitation Reactions and Titrations
Titration & pH curves [17.3].
ERT207 Analytical Chemistry Complexometric Titration
EDTA Titration of Ca2+ and Mg2+ in Natural Waters
Chapter 12 EDTA Titrations
Chem. 31 – 10/11 Lecture.
Complexometric titration Dr.Bhagure G.R.
Tutorial 7 Compleximetry.
VOLUMETRIC ANALYSIS B.Sc. Sneha S. Mule Assistant Professor
Presentation transcript:

EDTA Titration EDTA = Ethylenediaminetetraacetic acid Lewis acid : electron pair acceptor eg metal ions Lewis base : electron pair donor eg ligands A ligand that attaches to a metal ion through more than one ligand atom is called a chelating ligand or multidentate ligand

A titration based on complex formation is called complexometic titration The equilibrium constant for the reaction of a metal with a ligand is called the formation constant, Kf , or the stability constant Consider : Ag+ + NH3 Ag(NH3)+ Ag(NH3)+ + NH3 Ag(NH3)2+ Kf1 = Kf2 = [Ag(NH3)+] [Ag+][NH3] [Ag(NH3)2+] [Ag(NH3)+][NH3]

and the overall formation constant : Kf =Kf1 Kf2 = The overall reaction : Ag+ + 2NH3 = Ag(NH3)2+ and the overall formation constant : Kf =Kf1 Kf2 = [Ag(NH3)2+] [Ag+][NH3]2 Example : A divalent metal M2+ reacts with a ligand L to form a 1:1 complex : M2+ + L ML2+ Calculate the concentration of M2+ in a solution prepared by mixing equal volumes of 0.20 M M2+ and 0.20 M L. Given Kf = 1.0 x 108 Given Kf = 1.0 x 108 complex is sufficiently strong such that the reaction is virtually complete Since equal volumes were added initial concentration is halved

Let x = residual concentration of M2+ M2+ + L ML2+ x x 0.1 – x Kf = = 1.0 x 108 x = 3.2 x 10-5 M x2 0.1 - x Similarly, if L is a multidentate ligand and M + nL MLn then Kf = [MLn] [M][L]n

EDTA Complexes It can be represented as having four Ka values : EDTA is a hexaprotic system – H6Y2+ Neutral acid is tetraprotic – H4Y It can be represented as having four Ka values : H4Y H+ + H3Y- Ka1 = 1.0 x 10-2 H3Y- H+ + H2Y2- Ka2 = 2.2 x 10-3 H2Y2- H+ + HY3- Ka3 = 6.9 x 10-7 HY2- H+ + Y4- Ka4 = 5.5 x 10-11

CH Y = [Y4-] + [HY3-] + [H2Y2-] + [H3Y-] + [H4Y] 4 Hence in complexing with - +1 cation : Ag+ + Y4- = AgY3- Kf = +2 cation : Hg2+ + Y4- = HgY2- Kf = +3 cation : Fe3+ + Y4- = FeY- Kf = +n cation : Mn+ + Y4- = MYn-4 Kf = [MYn-4] [Mn+] [Y4-] [HgY2-] [Hg2+][Y4-] [FeY-] [Fe3+][Y4-] [AgY3-] [Ag+][Y4-] Fraction of the total EDTA species that exists as Y4- = a4 = [Y4-]/CH Y where CH Y = [Y4-] + [HY3-] + [H2Y2-] + [H3Y-] + [H4Y] 4

Substituting [Y4- ] = a4CH Y Kf = 4 a4Kf = = Kf’ 4 [MYn-4] [Mn+] a4CH Y [Mn+]CH Y Conditional formation constant – holds only for a particular pH – describes the formation of MYn-4 at any particular pH – allows us to look at EDTA complex formation as if the uncomplexed EDTA were all in one form Example : Consider the reaction: Fe3+ + EDTA FeY- (Kf = 1.3 x 1025; aY (at pH1) = 1.9 x 10-18 and aY (at pH4) = 3.8 x 10-9). Calculate the concentration of free Fe3+ in a solution of 0.10 M FeY- at pH4 and at pH1. 4-

Let x = [Fe3+] = [EDTA], thus = = 4.9 x 1016 (at pH4) Using Kf’ = a4Kf , at pH = 4 : Kf’ = (3.8 x 10-9)(1.3 x 1025) = 4.9 x 1016 at pH = 1 : Kf’ = (1.9 x 10-18)(1.3 x 1025) = 2.5 x 107 Let x = [Fe3+] = [EDTA], thus = = 4.9 x 1016 (at pH4) x = 1.4 x 10-9 M Similarly, at pH1: x = 6.4 x 10-5 M pH affects the stability of the complex. The Kf’ values show that the metal-EDTA complex becomes less stable at lower pH [FeY-] [Fe3+][EDTA] 0.1 - x x2

For a titration reaction to be effective, the equilibrium constant must be large the analyte and titrant should be completely reacted at the equivalence point Titration of Ca2+ with EDTA as a function of pH :

EDTA Titration Curves Titration is carried out by adding the chelating agent to the sample : Mn+ + EDTA MYn-4 Kf’ = a4Kf The titration curve is a graph of pM (= -log[M]) versus the volume of added EDTA Titration curve consists of 3 regions- Before the equivalence point : There is excess Mn+ in the solution after the EDTA has been consumed. Concentration of free metal ion = concentration of excess unreacted Mn+

At the equivalence point : [Mn+] = [EDTA] Free Mn+ is from the dissociation of MYn-4 : MYn-4 Mn+ + EDTA After the equivalence point : There is excess EDTA and virtually all the metal ion is in the MYn-4 form Example : Calculate the shape of the titration curve for the reaction of 50.0 ml of 0.0500 M Mg2+ (buffered to pH10.0) with 0.0500 M EDTA (Kf = 6.2 x 108 ; at pH10.0 : aY = 0.36) Mg2+ + EDTA MgY2- Using Kf’ = a4Kf = (0.36)(6.2 x 108) = 2.2 x 108

Since Kf’ is large the reaction goes to completion with each addition of titrant Before equivalence point : Consider the addition of 5.0 ml EDTA to the solution Moles of EDTA added = (0.005 l)(0.0500 M) = 2.5 x 10-4 Moles of Mg2+ present initially= (0.050 l)(0.050M) = 2.5 x 10-3 Moles of Mg2+ present after the addition of EDTA = (2.5 x 10-3 ) – (2.5 x 10-4) = 0.00225 [Mg2+] = = 0.0409 M pMg2+ = -log [Mg2+] =1.39 At equivalence point : [Mn+] = [EDTA] Volume of EDTA added = (2.5 x 10-3)/(0.0500M) = 50.0 ml 0.00225 0.055

Since there is negligible dissociation, [MgY2-] = = 0.025 M From: 0.0025 mol 0.100 l [MgY2-] [Mg2+][EDTA] 0.025 - x x2 Since there is negligible dissociation, [MgY2-] = = 0.025 M From: Mg2+ + EDTA MgY2- Let x =[Mg2+] = [EDTA], then Kf’ = = = 2.2 x 108 x = 1.07 x 10-5 M pMg2+ = -log [Mg2+] =4.97 After equivalence point : If 51.0 ml of EDTA is added there will be 1.0 ml excess EDTA in the solution

[EDTA] ={(0.001)(0.05M)}/(0.101 l) =4.95 x 10-4 M [MgY2-] =(2.5 x 10-3)/(0.101 l) =2.48 x 10-2 M Using Kf’ = = = 2.2 x 108 [Mg2+] = 2.3 x 10-7 M p[Mg2+] = -log [Mg2+] = 6.64 [MgY2-] [Mg2+][EDTA] 2.48 x 10-2 [Mg2+](4.95 x 10-4)

Metal Ion Indicators Methods to detect the end point in EDTA titrations are : metal ion indicators A metal ion indicator is a compound whose color changes when it binds to a metal ion (eg Eriochrome black T) This compound must bind metal less strongly than EDTA MgIn + EDTA MgEDTA + In (red) (colorless) (colorless) (blue) mercury electrode : measurement to potential glass pH electrode ion-selective electrode

EDTA Titration Techniques Direct Titration analyte is titrated with standard EDTA analyte is buffered to an appropriate pH at which the conditional formation constant for the metal-EDTA complex is large and the color of the free indicator is distinctly different from that of the metal-indicator complex Back titration a known excess of EDTA is added to the analyte the excess EDTA is titrated with a standard solution of a second metal this method is useful if - analyte precipitates in the absence of EDTA - the analyte reacts too slowly with EDTA under titration conditions - analyte blocks the indicator - metal used in back titration must not displace the analyte metal ion from its EDTA complex

Displacement titration Method is useful is the metal ions do not have a satisfactory indicator analyte is treated with excess Mg(EDTA)2- to displace Mg2+ Mn+ + MgY2- MYn-4 + Mg2+ - the displaced Mg2+ is titrated with standard EDTA Example : 2Ag+ + Ni(CN)42- 2Ag(CN)2- + Ni2+ (iv) Indirect titration Anions (such as SO42-, CrO42-, CO32- and S2-) that precipitate with certain metal ions can be analyzed with EDTA through indirect titration For example, SO42 can be precipitated with excess Ba2+. The BaSO4(s) is washed and boiled with excess EDTA at pH10 to bring Ba2+ back into solution as Ba(EDTA)2-. The excess EDTA is back titrated with Mg2+