Oxidation Number
Oxidation Number Rules
- A few simple rules help guide you through the process of determining the oxidation number of any element
- Remember, you are determining the oxidation state of a single atom
Oxidation Numbers
- The oxidation state of an atom is the charge that would exist on an individual atom if the bonding were completely ionic
- It is like the electronic ‘status’ of an element
- Oxidation numbers are used to
- Tell if oxidation or reduction has taken place
- Work out what has been oxidised and/or reduced
- Construct half equations and balance redox equations
Oxidation Numbers of Simple Ions
Oxidation Rules Table
Molecules or Compounds
- In molecules or compounds, the sum of the oxidation number on the atoms is zero
Oxidation Number in Molecules or Compounds
- Because CO2 is a neutral molecule, the sum of the oxidation number must be zero
- For this, one element must have a positive oxidation number and the other must be negative
How do you determine which is the positive one?
- The more electronegative species will have the negative value
- Electronegativity increases across a period and decreases down a group
- O is further to the right than C in the periodic table so it has the negative value
- From its position in the periodic table and/or
- The other element(s) present in the formula
- The oxidation states of all other atoms in their compounds can vary
- By following the oxidation number rules, the oxidation state of any atom in a compound or ion can be deduced
- The position of an element in the periodic table can act as a guide to the oxidation number
Oxidation Numbers & the Periodic Table
- Test your understanding on the following examples:
Worked Example
Deducing oxidation numbers
Give the oxidation number of the elements in bold in these compounds or ions:
a. P2O5
b. SO42-
c. H2S
d. Al2Cl6
e. NH3
f. ClO2-
Answers
Are oxidation numbers always whole numbers?
- The answer is yes and no
- When you try and work out the oxidation numbers of sulfur in the tetrathionate ion S4O62- you get an interesting result!
The oxidation number of sulfur in S4O62- is a fraction
- The fact that the oxidation number comes out to +2.5 does not mean it is possible to get half an oxidation number
- This is only a mathematical consequence of four sulfur atoms sharing +10 oxidation number
- Single atoms can only have an integer oxidation number, because you cannot have half an electron!
Roman numerals
- Roman numerals are used to show the oxidation states of transition metals which can have more than one oxidation state
- Iron can be both +2 and +3 so Roman numerals are used to distinguish between them
- Fe2+ in FeO is written as iron(II) oxide
- Fe3+ in Fe2O3 is written as iron(III) oxide
Redox Reactions & Equations
- Metals can react with acid to form a salt and hydrogen
Metal + acid → salt + hydrogen
- During this reaction, there are changes in oxidation number
- This means that the reaction can be classified as a redox reaction
Worked Example
Explain why each of the following reactions is a redox reaction:
- Zinc + hydrochloric acid → zinc chloride + hydrogen
- Magnesium + sulfuric acid → magnesium sulfate + hydrogen
Answer 1
Step 1: Write the balanced symbol equation
-
- Zn + 2HCl → ZnCl2 + H2
Step 2: Deduce the changes in oxidation number
-
- Zinc - starts at 0, changes to +2
- Hydrogen - starts at +1, changes to 0
- Chlorine - remains at -1 throughout
Step 3: Explain which species is reduced / oxidised
-
- Zinc is oxidised as its oxidation number increases from 0 to +2
- Hydrogen is reduced as its oxidation number decreases from +1 to 0
Answer 2
Step 1: Write the balanced symbol equation
-
- Mg + H2SO4 → MgSO4 + H2
Step 2: Deduce the changes in oxidation number
-
- Magnesium - starts at 0, changes to +2
- Hydrogen - starts at +1, changes to 0
- Sulfate ion - remains at -2 throughout
Step 3: Explain which species is reduced / oxidised
-
- Magnesium is oxidised as its oxidation number increases from 0 to +2
- Hydrogen is reduced as its oxidation number decreases from +1 to 0
Exam Tip
Remember that oxidation number increases in oxidation reactions and decreases in reductions reactions
If you are asked to explain why a reaction is a redox reaction, you should always talk about one of the following:
- Gain / loss of oxygen
- Gain / loss of hydrogen
- Gain / loss of electrons
- Changes in oxidation numbers
Simply saying that it a reaction is a redox reaction because "reduction and oxidation happen at the same time" is describing, not explaining
Interpreting Redox
We can identify the oxidation and reducing agents in a reaction by using the oxidation state.
- For example
- If we look at zinc, Zn, in the reaction above we can see that it increases from 0 to +2 in zinc sulfate, ZnSO4
- An increase in oxidation number indicates oxidation has occured
- Therefore zinc is the reducing agent
- If we look at sulfuric acid, H2SO4, the oxidation state of hydrogen has decreased from +1 to 0 in H2
- A decrease in oxidation number indicates reduction has occurred
- Therefore sulfuric acid is the oxidising agent
Worked Example
Answer
Step 1: Deduce the oxidation numbers of nitrogen and chlorine in the equation (hydrogen = +1, oxygen = -2, sodium = +1
N in NH3 is -3
Cl in NaClO is +1
N in N2H4 is -2
Cl in NaCl is -1
Step 2
Identify which species has been oxidised and which has been reduced by looking at the oxidation numbers
Nitrogen is increasing in oxidation number, therefore has been oxidised
Chlorine is decreasing in oxidation number, therefore has been reduced
Step 3
Identify the oxidising and reducing agent
NH3 is the reducing agent (it has been oxidised itself)
NaClO is the oxidising agent (it has been reduced itself)
Remember, the whole species is the reducing agent, not just the element (e.g. NH3 is the reducing agent, not N on its own)
