Pharmaceutical Analytical Chemistry 3 Lecture Notes PDF

Summary

This document presents lecture notes for Pharmaceutical Analytical Chemistry 3 (PA203) for the 2024/2025 academic year. The lecture focuses on applications of redox titrations, covering principles, techniques, and quantitative analysis. The document includes topics ranging from redox reactions to the determination of oxides and anions.

Full Transcript

Academic Year: 2024/2025

Pharmaceutical Analytical Chemistry 3
(PA203)

Lecture No. (3)

Applications of Redox Titrations

By
Dr: Ahmed Mogahed Haredy
Pharmaceutical Analytical Chemistry Department
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Lecture’s Aim
1. Understanding Redox Reactions: Explain the principles of oxidation-
reduction (redox) reactions, including oxidation states and electron transfer
concepts.
2. Titration Techniques: Introduce the different types of redox titrations and
discuss how they are performed.
3. Quantitative Analysis: Demonstrate how redox titrations can be used for
quantitative analysis to determine the concentration of oxidizing or
reducing agents in a solution.

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Lecture’s Competencies
1. Knowledge of Redox Principles:
Understand the concepts of oxidation and reduction.
Identify oxidizing and reducing agents in reactions.
2. Data Analysis and Interpretation:
Analyze titration data, including the ability to construct and interpret titration curves.
Calculate concentrations and equivalents based on titration results.
3. Application of Theoretical Concepts:
Apply stoichiometric principles to solve problems related to redox reactions.
Relate redox titration results to real-world scenarios in various fields, such as chemistry,
environmental science, and medicine.
4. Critical Thinking and Problem Solving:
Evaluate experimental designs and troubleshoot issues encountered during titrations.
Assess the reliability and limitations of redox titration methods.
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Lecture’s Contents
1. Free elements
I. Reducing free elements (Metallic iron)
II. Oxidizing free elements (Free halogens)
2. Determination of peroxides:
a. H2O2 b. ZnO2 c. Higher oxides of heavy metals.
3. Determination of oxides
4. Determination of cations
A. Determination of Iron:
1. Ferrous
2. Ferric
3. Substances that reduce Fe+3 to Fe+2
4. Substances that oxidize Fe+2 to Fe+3
5. Determination of ferrocyanide and ferricyanide
B. Determination of HgCl2
C. Determination of cations that form insoluble oxalates.
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Lecture’s Contents
5. Determination of Anions
A. Determination of soluble oxalates
B. Determination of sulphide, sulphite, thiosulphate,
sulphate & persulphates.
C. Determination of halides, chlorate and hypochlorite.
6. Determination of moisture content (Karl-Fischer reagent)
7. Determination of organic pharmaceutical compounds
8. Analysis of mixtures.

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Standard
Oxidation
Potential (Eo)

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1. Free elements
1. Metallic iron (Fe)
It can be determined by dissolving it in a ferric chloride solution.
The produced ferrous chloride is titrated with standard
permanganate in the presence of Zimmermann reagent.

Fe + 2FeCl3 3FeCl2
Iron oxides do not interfere.
≠
St. KMnO4
(self indicator)
in the presence of
Zimmermann reagent
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1. Free elements
2. Free halogens
Iodine can be determined by direct titration with sodium
thiosulphate solution.
Bromine or chlorine displaces iodine from potassium iodide.

I2 + 2Na2S2O3 → 2NaI + Na2S4O6 (sod. tetrathionate)

Br2 + 2KI → I2 + 2KBr
Cl2 + 2KI → I2 + 2KCl
≠
Stand. Na2S2O3
(Using starch as indicator)

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2. Determination of peroxides
1. Hydrogen peroxide
A. as reducing agent
By direct titration  Ce+4 (using ferroin indicator)
2Ce+4 + H2O2 → 2Ce+3 + O2 + 2H+
B. as an oxidizing agent
By direct titration  KMnO4. (self indicator)
2MnO4− + 5H2O2 + 6H+ → 2Mn+2 + 5O2 + 3H2O
(iodometrically) H2O2 + 2H+ + 2I− → I2 + 2H2O
≠
Stand. Na2S2O3
2. Zinc peroxide (Using starch as an indicator)
ZnO2 + 2H+ → Zn+2 + H2O2  Ce+4, KMnO4 or + KI → I2  S2O3-2.
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2. Determination of peroxides
Organic peroxides
1. Carbamide peroxide
✓ Topical antiseptic and disinfectant solution
H2N-CO-NH2..H2O2 → H2N-CO-NH2 + H2O2
✓ is assayed for H2O2 content iodometrically

2. Hydrous benzoyl peroxide
✓ Keratolytic and keratogenic agents for acne.
✓ It can be determined iodometrically.
(C6H5COO)2 + 2I− + 2H+ → 2C6H5COOH + I2

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3. Determination of oxides
1. Higher oxides of manganese and heavy metals
as MnO2, PbO2, Pb3O4
a. Iodometrically
MnO2 + 4HCl → MnCl2 + Cl2 + 2H2O
Cl2 + 2KI → I2  S2O3−2
b. Indirect titration with reducing agents
MnO2 + 2Fe 2+ + 4H+ → Mn2+ + 2Fe 3+ + 2H2O
MnO2 + C2O42- + 4H+ → Mn2+ + 2CO2 + 2H2O
2MnO2 + 2AsO33- + 4H+ → 2Mn2+ + 2AsO43- + 2H2O
Known excess ≠ Stand. KMnO4
standard (self indicator)

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3. Determination of oxides

PbO can be determined by dissolving the sample in glacial
acetic acid → lead acetate and precipitating it as lead oxalate
PbO + CH3COOH → Pb (CH3COO)2 + 2H+
Pb (CH3COO)2 + H2C2O4 → Pb C2O4  + 2 CH3COOH
Known excess Filter and wash the ppt
standard
≠
Stand. KMnO4
(self indicator)

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4. Determination of Cations
A. Iron
I. Ferrous salts: ferrous sulphate (FeSO4), ferrous ammonium
sulphate ((NH₄)₂Fe(SO₄)₂)(Mohr’s salt), ferrous carbonate
(FeCO3), ferrous sulphide (FeS),
1. Fe+2  KMnO4 after addition of Zimmermann’s reagent,
self indicator.
2. Fe+2  K2Cr2O7 after adding H3PO4 and internal redox
(diphenylamine) or external indicator.
3. Fe+2  Ce+4, irreversible methyl red indicator.
4. Fe+2  I2 in presence of F− or PO4−3 using starch.

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4. Determination of Cations
A. Iron
II. Ferric salts: by three methods
✓Ferric (Fe3+) reduced to (Fe2+) by pre-reductants
1- SnCl2 + Fe+3 → SnCl4 + Fe+2  KMnO4
after the addition of Zimmermann’s reagent, the self-indicator
2- Zn and H2SO4:
2Fe+3 + Znº + H+ → Zn+2 + 2Fe+2  KMnO4
H2SO4 accelerates the reduction by Znº, and the unreacted Znº
is removed by filtration.
3- Amalgamated Znº (Znº + HgCl2).
Excellent reducing agent (Jones reductor).

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4. Determination of Cations
A. Iron
✓ Iodometrically: Fe+3/Fe+2 system E°= 0.77
I2/2I− system E°= 0.54
You must  difference between the two systems
either by  I− conc. by addition of XSS I− or  I2 conc. by extraction with
immiscible solvent as CHCl3 or CCl4.
Fe+3 + I− → Fe+2 + I2  S2O3-2 using starch
✓ Direct titration with titanous chloride
using methylene blue (irreversible) or thiocyanate as indicators (the
endpoint is colorless due to the disappearance of either the blue color of
MB or the red color of Fe(SCN)3, which is formed at the beginning)
FeCl3 ≠ TiCl3 → FeCl2 + TiCl4

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4. Determination of Cations
A. Iron
III. Reductants that reduce Fe+3 → Fe+2 :
1- SnCl2 + Fe3+ → SnCl4 + Fe2+  KMnO4
2- Znº + 2Fe3+ → Zn+2 + 2Fe2+  KMnO4
3- Feº + 2Fe3+ → 3Fe2+  KMnO4

IV. Oxidants that oxidize Fe+2 → Fe+3 :
1- K2S2O8 + 2Fe2+ + 2H+ → 2Fe3+ + 2KHSO4

2- KClO3 + 6Fe2+ + 6H+ → 6Fe3+ + KCl + 3H2O

3- MnO2 + 2Fe2+ + 4H+ → 2Fe3+ + Mn2+ + 2H2O
Known excess
standard ≠ Stand. KMnO4 or K2Cr2O7
(self indicator) (Ferroin ind.)

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4. Determination of Cations
A. Iron
V. Ferrocyanide
By direct titration  KMnO4 or  Ce4+
1- 5[Fe(CN)6]4-  MnO4- +8H+→ 5[Fe(CN)6]3- + Mn2++3H2O
(self indicator)
2- [Fe(CN)6]4-  Ce4+ → [Fe(CN)6]3- + Ce3+
(ferroin indicator)
Ferricyanide
1- By iodometrical titration
2[Fe(CN)6]3- + 2I- → 2[Fe(CN)6]4- + I2  S2O3-2 (starch)
we add H2SO4 and ZnSO4 (to precipitate Zn2[Fe(CN)6]) to ↑↑ the E° of
[ferri]/[ferro] to oxidize iodide to iodine.
2- [Fe(CN)6]3- + pre-reductants → [Fe(CN)6]4-  MnO4-
Remove xss
e.g., Sulphite or sulphide, or sod. peroxide
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4. Determination of Cations
B. Determination of HgCl2
HgCl2 is reduced firstly to Hg° by HCHO in Ca(OH)2 medium.
Hg2+ + HCHO + 3OH- → Hg° + HCOO- + H2O
Hg° + I2 → HgI2  + 2I- → [HgI4]2-
known red ppt colorless
Excess stand
complex
≠
Stand. Na2S2O3
(starch as an indicator)

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4. Determination of Cations
C. Cations form insoluble oxalates.
(Ca2+, Ba2+ Sr2+, Mg2+, Cd2+, Bi3+, Zn2+, Ni2+, Co2+ & Pb2+)
Ca2+ + H2C2O4 → Ca C2O4  + xss. H2C2O4
known Filter and then follow one of the
Excess stand wash the ppt 2 ways
(i) The washed precipitate is dissolved in dil. H2SO4 and ≠ KMnO4
at 60°C. or
(ii) The excess oxalic acid in the filtrate and washing is back
titrated with standard KMnO4 at 60°C.
Oxidizing substances such as K2S2O8, KClO3, NO3-, and MnO2 can
be determined by treating them with a known excess of oxalic acid.
The residual oxalic acid is then back-titrated with standard KMnO4.
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5. Determination of Anions
A. Soluble oxalates.

Soluble oxalates  KMnO4 or Ce+4 in the
presence of sulphuric acid and heating to 60°C.

The slow reaction at the start becomes rapid
after forming the reduction product (Mn+2 or
Ce+3).

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5. Determination of Direct titration
Anions 1. Sulphide S−2 ≠ I2 → 2I− + Sº 
b. S2-, SO32-, S2O32- & Use dilute soln. to decrease the inclusion of I2 by Sº
SO42- 2. Thiosulphate 2S2O3−2 ≠ I2 → S4O6−2 + 2I−
Back titration.
3. Sulphite SO3−2 + I2 + H2O → SO4−2 + 2I− + 2H+
Known xss. St. S2O3−2
≠ (starch indicator)
standard

4. Sulphate SO4−2 + BaCrO4 → BaSO4 + CrO4−2 (filtrate)
2CrO4−2 (filtrate) + 2H+ → Cr2O7−2 + H2O
Iodometrically +2KI → I2  S2O3−2 (starch)

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5. Determination of Anions
C. Determination of halides, ClO3− and ClO−

Chlorates (ClO3−) & Hypochlorites (ClO−)
Iodometrically
- - + -
ClO3 + 6I + 6H Cl + 3I2 + 3H2O
Chlorate

ClO- + 2I- + 2H+ Cl- + I2 + H2O
Hypochlorite
≠
Stand. Na2S2O3
(starch as an indicator)

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5. Determination of Anions
C. Determination of halides, ClO3− and ClO−
✓e.g.,1: Chlorine in bleaching powder
(calcium hypochlorite + basic chloride).
Ca(OCl)2 CaCl2.Ca(OH)2.H2O
+ 4H+ → Cl2 + Ca2+ + 2H2O
Acetic acid is used for acidification,
e.g., 2,N-chlororganic compounds are used as water
disinfectants; these in water release hypochlorous acid
(HOCl), which is the active germicidal species.
ClO− + 2I− + 2H+ → Cl− + I2 + H2O (iodometrically)
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5. Determination of Anions
C. Determination of halides, ClO3− and ClO−

(Chiniofon)

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Oxygen flask combustion method
1. The compound (e.g.,Chiniofon) is wrapped in filter paper
attached to pt. wire and sealed in the stopper of a special
oxygen-filled flask containing dilute Na2S2O5 (sodium
metabisulphite) solution.

2. Combustion is complete
within 30 sec at 1200°C.

3. The resulting iodine is
absorbed (reduced) by
Na2S2O5 forming iodide

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6. Determination of moisture content
(Karl-Fischer reagent)
Reagent: I2 + SO2 + anhyd. CH3OH and anhyd. pyridine.
Sample containing moisture + reagent until the yellow color
of the xss iodine appears.
SO2 + I2 + H2O → SO3 + 2HI

3 N + SO3 + 2HI 2 N-HI + N-SO3

+ CH3OH

SO4CH3
N
H
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7. Determination of organic pharmaceutical compounds
Vitamin C (ascorbic acid) Iodimetrically

HO OH O O
+
H
+ I2 + 2HI
O O CH CH2 O O CH CH2
OH OH OH OH
Polyhydroxy Alcohols
Glycerol can be determined iodometrically:
3C3H8O3 + 7K2Cr2O7 + 28H2SO4 → 9CO2 + 40H2O + 7Cr2(SO4) + 7K2SO4
Known excess
standard + 2KI → I2 ≠ Standard Na2S2O3 (chloroform)
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7. Determination Mercaptans (Thiol) compounds
of organic Generally 2RSH ≠ I2 → RS-SR + 2HI
e.g., Dimercaprol, Thioglycollic acid, D-penicillamine; can be determined
pharmaceutical iodimetrically.
compounds CH2 SH CH2 S S CH2
2 CH SH ≠+ 2I CH S S CH + 4HI
2

CH2 OH CH2 OH CH2OH
Dimercaprol
CH2 SH NaHCO3 CH2 S S CH2
2 ≠+ I2 + 2HI
COOH COOH COOH
Thioglycollic acid
disulphide
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8. Analysis of Mixtures
1. Acetic & formic acids
(Total ≠ OH ─ [ph.ph.] & formic ≠ MnO4─)
2. Oxalic acid & sulphuric acid
(Total ≠ OH ─ [ph.ph.] & oxalic ≠ MnO4─)
3. Phenol & salicylic acid
(Total ≠ bromometrically & salicylic acid ≠ OH ─ [ph.ph.])
4. I2 & KI
(Total I2/I− by Andrew's & I2 ≠ S2O3 2─ )
5. Ferrous oxalate & oxalic acid (protoxalate)
(Total ≠ MnO4 ─ & the produced Fe3+ pass through red. ≠ MnO4 ─ or
iodometrically)

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Lecture’s References

"Analytical Chemistry" by Gary D. Christian
"Quantitative Chemical Analysis" by Daniel C. Harris
"Chemistry: A Molecular Approach" by Nivaldo J. Tro
"Principles of Instrumental Analysis" by Douglas A. Skoog, F.
James Holler, and Timothy A. Nieman
"Analytical Chemistry: A Modern Approach to Analytical
Science" by David Harvey

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