Balancing Redox Reactions: The Half-Equation Method

What Are Redox Reactions?

Redox stands for Reduction-Oxidation — reactions where electrons are transferred between species. They are among the most important reactions in chemistry, from rusting to respiration to batteries.

Remember with the mnemonic OIL RIG:

Oxidation Is Loss (of electrons)
Reduction Is Gain (of electrons)

Learning Goals: By the end of this guide, you should be able to:

Assign oxidation numbers to any element in a compound.

Identify which species is oxidised and which is reduced.

Write and balance half-equations.

Combine half-equations into overall balanced redox equations.

Balance equations in acidic and basic solutions.

Oxidation Numbers — The Rules

Rule	Example
Elements in their natural state = 0	$Fe = 0$ , $O_2 = 0$
Monoatomic ions = their charge	$Na^+ = +1$ , $Cl^- = -1$
Oxygen is usually -2	Exception: peroxides ( $-1$ )
Hydrogen is usually +1	Exception: metal hydrides ( $-1$ )
Fluorine is always -1	Most electronegative element
Sum of oxidation numbers = overall charge	e.g., in $SO_4^{2-}$ : $S + 4(-2) = -2$ , so $S = +6$

The Half-Equation Method

Step-by-Step (Acidic Solution)

Assign oxidation numbers to identify what's oxidised and what's reduced.
Write two separate half-equations — one for oxidation, one for reduction.
Balance atoms other than O and H.
Balance O by adding $H_2O$ .
Balance H by adding $H^+$ .
Balance charge by adding electrons ( $e^-$ ).
Equalise electrons in both half-equations (multiply if needed).
Add the half-equations and cancel common species.

Example: $Fe^{2+}$ and $MnO_4^-$ in Acidic Solution

Oxidation half: $Fe^{2+} \rightarrow Fe^{3+} + e^-$

Reduction half (balance step by step):

$MnO_4^- \rightarrow Mn^{2+}$
Balance O: $MnO_4^- \rightarrow Mn^{2+} + 4H_2O$
Balance H: $MnO_4^- + 8H^+ \rightarrow Mn^{2+} + 4H_2O$
Balance charge: $MnO_4^- + 8H^+ + 5e^- \rightarrow Mn^{2+} + 4H_2O$

Combine: Multiply oxidation by 5 to equalise electrons:

5Fe^{2+} + MnO_4^- + 8H^+ \rightarrow 5Fe^{3+} + Mn^{2+} + 4H_2O

Redox Equation Balancer

Enter any redox reaction and watch the half-equations being balanced step by step. See oxidation numbers change and electrons transfer in real time.

Launch Redox Balancer

Oxidising and Reducing Agents

Term	Definition	What Happens to It
Oxidising agent	Causes oxidation in another species	Gets reduced itself (gains electrons)
Reducing agent	Causes reduction in another species	Gets oxidised itself (loses electrons)

In the example above: $MnO_4^-$ is the oxidising agent (it gets reduced), and $Fe^{2+}$ is the reducing agent (it gets oxidised).

Worked Examples

Example 1: Assign Oxidation Numbers in $Cr_2O_7^{2-}$

2(Cr) + 7(-2) = -2 \quad \Rightarrow \quad 2Cr - 14 = -2 \quad \Rightarrow \quad Cr = +6

Chromium is in oxidation state +6.

Example 2: Balance $Cu + HNO_3 \rightarrow Cu(NO_3)_2 + NO_2 + H_2O$

Oxidation: $Cu \rightarrow Cu^{2+} + 2e^-$

Reduction: $NO_3^- + 2H^+ + e^- \rightarrow NO_2 + H_2O$

Multiply reduction by 2: $2NO_3^- + 4H^+ + 2e^- \rightarrow 2NO_2 + 2H_2O$

Overall: $Cu + 2NO_3^- + 4H^+ \rightarrow Cu^{2+} + 2NO_2 + 2H_2O$

Full equation: $Cu + 4HNO_3 \rightarrow Cu(NO_3)_2 + 2NO_2 + 2H_2O$

Example 3: Identifying Redox in Displacement

Question: $Zn + CuSO_4 \rightarrow ZnSO_4 + Cu$ . Identify what is oxidised and reduced.

Solution:

$Zn$ : $0 \rightarrow +2$ → oxidised (loses 2 electrons, reducing agent)
$Cu^{2+}$ : $+2 \rightarrow 0$ → reduced (gains 2 electrons, oxidising agent)

Common Mistakes

Not checking that electron counts match — Before combining half-equations, the number of electrons lost must equal the number gained. If they don't, multiply one or both half-equations.
Forgetting to balance O and H — In acidic solution: use $H_2O$ for oxygen, $H^+$ for hydrogen. In basic solution: also add $OH^-$ at the end.
Assigning wrong oxidation numbers — Always check oxygen (-2 normally) and hydrogen (+1 normally) before solving for the unknown element.
Mixing up oxidising and reducing agents — The oxidising agent is reduced (gains electrons). This is counterintuitive. Remember: "the oxidising agent gets reduced."

Exam Tips (A-Level / AP / IB)

Show all steps explicitly: assign oxidation numbers → write half-equations → balance → combine.
When balancing, check your final equation: same number of each element on both sides, same total charge on both sides.
On the AP exam, you often need to identify the oxidising and reducing agents AND write the net ionic equation.
For colour changes involving transition metals, know the common ones: $MnO_4^-$ (purple) → $Mn^{2+}$ (colourless), $Cr_2O_7^{2-}$ (orange) → $Cr^{3+}$ (green).

Frequently Asked Questions

What is the difference between oxidation and reduction?

Oxidation is the loss of electrons (increase in oxidation number). Reduction is the gain of electrons (decrease in oxidation number). They always occur together — you cannot have one without the other.

How do you identify a redox reaction?

Check if any element changes its oxidation number. If at least one element is oxidised and one is reduced, it's a redox reaction. If no oxidation numbers change, it's not redox.

Why does the half-equation method work?

It ensures conservation of both mass and charge. By balancing each half separately and then combining, you guarantee that electrons lost equal electrons gained, and all atoms and charges are balanced.

Electrochemistry Cells — Apply redox reactions to generate electricity.
Limiting Reagents — Stoichiometric calculations with redox reactions.
Periodic Trends — How position in the periodic table affects oxidising/reducing power.