electroanalytical methods chapter chapter 2 2 electroanalytical methods electrogravimetry ...
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Electroanalytical Electroanalytical methodsmethods
ChapterChapter 2
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Electroanalytical methods
ElectrogravimetryElectrogravimetry Coulometry Coulometry PotentiometryPotentiometry VoltammetryVoltammetry
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PotentiometryPotentiometry
Fundamentals of potentiometry
Reference electrodes
Indicator and ion selective electrodes
Instrumentation and measurement of cell electromotive force (e.m.f)
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Fundamentals of potentiometry
When a metal is immersed in a solution containing its own ions, the potential difference is established between the metal and the solution
Ox + ne Red
Ra
a
nF
RT 0ln
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Fundamentals of potentiometry
M n+ + ne = M
= + (RT/nF) ln Mn+
Nernst equation
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Fundamentals of potentiometry
Indicator electrode
+Reference electrode
+Solution
Cell
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Fundamentals of potentiometry
M M n+ reference electrode
E = (+) - (-) + L
E = (+) - (-)
= r - - (RT/nF) ln Mn+
Liquid junction potential
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Reference electrodesReference electrodes
Hydrogen electrode
Calomel electrode
Silver – silver chloride electrode
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Calomel electrode
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Calomel electrode
Hg│Hg2Cl2 , KCl(xM)‖
Hg2Cl2(s)+ 2e 2Hg(l)+ 2Cl-
Electrode potential
= Hg2Cl2 / Hg + (RT/nF) ln (1/ Cl-2)
= Hg2Cl2 / Hg - 0.059 lg Cl-
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Silver – silver chloride electrode
Ag│AgCl , KCl(xM)‖
AgCl(s)+ e Ag(s)+Cl-
Electrode potential
= AgCl / Ag + (RT/nF) ln (1/ Cl-)
= AgCl / Ag - 0.059 lg Cl-
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Indicator and ion selective electrodes
Indicator electrode
---The potential depends on the activity of a particular ionic species which it is desired to quantify
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Indicator and ion selective electrodes
Electrode of the first kind
Electrode of the second kind
The glass electrode
Crystalline membrane electrode
Biochemical electrode
Inert electrodeMetal Metal electrodelectrodee
MembraneMembrane electrodeelectrode
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Electrode of the first kind
Indicator and ion selective electrodes
---The ion to be determined is directly involved in the electrode reaction
= M n+
/ M+ (RT/nF) ln M
n+
Metal M immersed in a solution of M n+
ion
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Electrode of the second kind
Indicator and ion selective electrodes
Silver – silver chloride electrode
--- coating a silver wire with silver choloride
AgCl(s)+ e Ag(s)+Cl-
= AgCl / Ag + (RT/nF) ln (1/ Cl-)
= AgCl / Ag - 0.059 lg Cl-
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Fe 3+ + e Fe 2+
= Fe 3+ / Fe2+ + (RT/nF) ln (Fe3+ / Fe
2+)
Inert electrode
---An inert electrode (Pt) is place in a system containing both an oxidizing agent and its reduction product
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The glass electrode
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The glass electrode
Composition
SiO2 72% + Na2O 22% + CaO 6%
SiO2 63% + Li2O 28% + Cs2O 2%
+ BaO 4% + La2O3 3%
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The glass electrode
Theory
--- Ion exchange process
glass = K + (RT/nF) ln H+
= K’ – 0.059 pH
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The glass electrode
properties
Can be used in the presence of strong oxidants and reductants
Can be used in viscous media
Can be used in the presence of proteins
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The glass electrode
properties
High resistance
Acid error and alkaline error
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Crystalline membrane electrode
composition
Lanthanum fluoride eletrode
Crystal of lanthanum fluoride+0.1 mol/L NaF – 0.1 mol/L NaCl+
Silver – silver chloride electrode
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Crystalline membrane electrode
Theory
Lattice defect
membrane = K - (RT/nF) ln F-
= K – 0.059 lg F-
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Crystalline membrane electrode
properties
Detection limit ~ 10-7 mol/L
Interference ~ OH-
pH range ~ 5 - 6
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Gas – sensing electrode
NH3 – NH4Cl
CO2 – NaHCO3
NO2 –NaNO2
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Biochemical electrode
Urea electrode
CO(NH2)2 + H2O + 2H+ 2NH4+ +
CO2
urease
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Instrumentation
Determination of pH
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Determination of pH
Glass electrode│ Solution X
││ SCE
E = SCE - glass
= SCE – ( AgCl / Ag + K + (RT/nF) ln H+)
E = K’ + (2.303 RT /F) pH
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E x= K’ x + (2.303 RT /F) pH x
Determination of pH
E s= K’ s + (2.303 RT /F) pH s
K’ x = K’ s
pH x = pH s + (E x - E s) F/2.303RT
--- Operational definition
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Determination of pH
Solution
0.05 M potassium hydrogenphthalate
0.025 M KH2PO4
0.025 M Na2HPO4
0.01 M Borax
pH 4.004 6.864 9.182
pH standard solution (25 Cº)
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Determination of fluoride
membrane = K ± (0.059/n) lg
Calibration curve
Standard addition
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Determination of fluoride
Calibration curve
Standard solutions
Total ionic strength adjustment buffer(TISAB)NaClNaAc - HAc
Sodium citrate
Ionic strength
pH
Interference
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Standard addition
Determination of fluoride
E1 = kc + k log y1 C1
E2 = kc + k log y1 (V1C1 + V2Cs)/(V1 + V2)
E2 - E1 = k log (V1C1 + V2Cs)/ C1(V1 + V2)
C1 = Cs/(10 E/k(1+V1/V2) – V1/V2)
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