PF1009 2024 12 Redox Reactions PDF

Summary

This document is a lecture on Redox Reactions in Pharmaceutical Chemistry. It covers concepts like oxidation numbers, and redox reactions in acidic and basic solutions. Dr. J.J. Keating is the instructor.

Full Transcript

Pharmaceutical Chemistry

Redox Reactions

Dr. J.J. Keating

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 Oxidation Numbers
The effective charge of an atom
The oxidation number of an elemental substance is zero
The oxidation number of a monoatomic ion = charge number of that ion.

Rules for assigning oxidation numbers
The sum of the oxidation numbers of all atoms in the species is equal to its total charge.
Atoms in their elemental form = 0

For elements of Group I, +1
For elements of Group II, +2
For elements of Group III (except B), +3 for M3+; +1 for M+
For elements of Group IV (except C, Si), +4 for M4+; +2 for M2+

For H, +1 in combination with non-metals, –1 in combination with metals

For F, –1 in all its compounds

For O, –2 unless combined with F,
–1 in peroxides (O22–),
–½ in superoxides (O2–),
–⅓ in ozonides (O3–).
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 Redox Reactions
Oxidation is electron loss.
Reduction is electron gain.

2Mg + O2 → 2MgO

A redox reaction is a reaction in which oxidation and reduction take place.

Oxidising agent – removes electrons and becomes reduced in a reaction. An element in
the oxidising agent undergoes a decrease in oxidation number.

Reducing agent – supplies electrons and becomes oxidised in a reaction. An element in
the reducing agent undergoes an increase in oxidation number.

2Mg + O2 → 2MgO (exothermic) 3
 Redox Reactions in Acidic Solution

O O

HO OH
MnO4– + H2C2O4 → Mn2+ + CO2
KMnO4 oxalic acid (H2C2O4)
potassium permanganate ethane-1,2-dioic acid

1. Identify the oxidised and reduced species from the changes in oxidation numbers.
2. Write two skeletal equations for the half-reactions.
3. Balance by inspection all elements in the half-reactions except O, H and the charge.
4. Balance O atoms in each half-reaction by adding H2O.
5. Balance H atoms in each half-reaction by adding H+.
6. Balance the electric charges in each half-reaction by adding electrons.
7. Prepare the two half-reactions for summation by making the number of electrons in the
same in both. To do this, you may have to initially independently multiply one or both
reactions across the reaction by a factor.
8. Combine the two half-reactions by adding them together (treat them as adding two
simultaneous equations) and simplify (combine common species across the balanced
equation).
9. Check the equation is balanced by the numbers of each atoms and overall charge on
each side of the equation.

2MnO4– + 6H+ + 5H2C2O4 → 2Mn2+ + 10CO2 + 8H2O
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 Redox Reactions in Basic Solution

KMnO4
potassium permanganate
MnO4– + Br– → MnO2 + BrO3–
BrO3 –

bromate

As per balancing redox reactions in acidic aqueous solution, but add the following steps
between Step 5 and 6 on the previous slide:

After step 5, add the same number of OH– ions to both sides of each half-reaction as
there are H+ in each half-reaction.

Combine H+ and OH– in each half-reaction to form H2O.

If, at this stage, H2O is present on both sides of each half-reaction, bring H 2O to one
side of each half-reaction.

Continue with Step 6 on the previous slide.

2MnO4– + H2O + Br– → 2MnO2 + 2OH– + BrO3–
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 Redox Reactions in Basic Solution

NO3– Zn(OH4)2– NH3
Zn + NO3– → Zn(OH)42– + NH3
nitrate zinc tetrahydroxide ammonia

The unbalanced redox reaction shown above takes place in aqueous base, and involves
the reaction of zinc metal and nitrate ions, forming zinc tetrahydroxide and ammonia.

The balanced reaction is:

4Zn + 7OH– + NO3– + 6H2O → 4Zn(OH)42– + NH3

Check the balanced reaction is correct:

4 x Zn → 4 x Zn
1xN → 1xN
16 x O → 16 x O
19 x H → 19 x H
8 e– → 8 e– 6
 Element Activity Series
List of elements arranged such that a metal can reduce the cations formed by any of the
metals below it in the list.

Zn can reduce Cu2+, but not vice versa. Zn + Cu2+ → Zn2+ + Cu

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