The oxidation number of an element in a compound is evaluated on the basis of certain rules. Which of the following rules is not correct in this respect?

The oxidation number of hydrogen is always +1

The algebraic sum of all the oxidation numbers in a compound is zero

An element in the free or the uncombined state bears oxidation number zero

In all its compounds, the oxidation number of fluorine is – 1

Redox Reactions - Examples, Types, Applications, Balancing

Redox reactions are oxidation-reduction chemical reactions in which the reactants undergo a change in their oxidation states. The term ‘redox’ is a short form of reduction-oxidation. All the redox reactions can be broken down into two different processes – a reduction process and an oxidation process.

The oxidation and reduction reactions always occur simultaneously in the redox reaction or Oxidation-Reduction reaction. The substance getting reduced in a chemical reaction is known as the oxidizing agent, while a substance that is getting oxidized is known as the reducing agent.

JEE Main 2021 LIVE Chemistry Paper Solutions 24-Feb Shift-1 Memory-Based

Types
Examples
Oxidation and Reduction
Oxidizing and Reducing Agents
Identification of Oxidizing and Reducing Agents
Balancing Redox Reaction
Problems
Applications
FAQs

What are Redox Reactions?

A redox reaction can be defined as a chemical reaction in which electrons are transferred between two reactants participating in it. This transfer of electrons can be identified by observing the changes in the oxidation states of the reacting species.

An illustration detailing the electron transfer between two reactants in a redox reaction is provided below.

In the illustration provided below, it can be observed that the reactant, an electron, was removed from reactant A and this reactant is oxidized. Similarly, reactant B was handed an electron and was therefore reduced.

Redox reaction image 1

The loss of electrons and the corresponding increase in the oxidation state of a given reactant is called oxidation. The gain of electrons and the corresponding decrease in the oxidation state of a reactant is called reduction.

Electron-accepting species which tend to undergo a reduction in redox reactions are called oxidizing agents. An electron-donating species which tends to hand over electrons can be referred to as a reducing agent. These species tend to undergo oxidation. It can be noted that any redox reaction can be broken down into two half-reactions, namely the oxidation half-reaction and the reduction half-reaction.

When writing these half-reactions separately, each of them must be balanced in a way that all the electrons are accounted for.

Types of Redox Reactions

The different types of redox reactions are:

Decomposition Reaction
Combination Reaction
Displacement Reaction
Disproportionation Reactions

Decomposition Reaction

This kind of reaction involves the breakdown of a compound into different compounds. Examples of these types of reactions are:

2NaH → 2Na + H₂
2H₂O → 2H₂+ O₂
Na₂CO₃ → Na₂O + CO₂

All the above reactions result in the breakdown of smaller chemical compounds in the form of AB → A + B

But, there is a special case that confirms that all the decomposition reactions are not redox reactions.

For example CaCO₃ → CaO + CO₂

Also Read: Types of Reactions

Combination Reaction

These reactions are the opposite of decomposition reaction and hence involve the combination of two compounds to form a single compound in the form of A + B → AB. For example:

H₂ + Cl₂ → 2HClC+O₂→CO₂
4Fe+ 3O₂→2Fe₂O₃

Displacement Reaction

In this kind of reaction, an atom or an ion in a compound is replaced by an atom or an ion of another element. It can be represented in the form of X + YZ → XZ + Y. Further displacement reaction can be categorized into

Metal displacement Reaction
Non-metal displacement Reaction

Metal Displacement

In this type of reaction, a metal present in the compound is displaced by another metal. These types of reactions find their application in metallurgical processes where pure metals are obtained from their ores.

For example CuSO₄+Zn→Cu+ZnSO₄

Non-Metal Displacement

In this type of reaction, we can find a hydrogen displacement and sometimes rarely occurring reactions involving oxygen displacement.

Disproportionation Reactions

The reactions in which a single reactant is oxidized and reduced is known as Disproportionation reactions.

For example: P₄ + 3NaOH + 3H₂O → 3NaH₂PO₂ + PH₃

Disproportionation Reaction Video Lesson

Examples of Redox Reactions

A few examples of redox reactions, along with their oxidation and reduction half-reactions are provided in this subsection.

Example 1: Reaction Between Hydrogen and Fluorine

In the reaction between hydrogen and fluorine, the hydrogen is oxidized whereas the fluorine is reduced. The reaction can be written as follows.

H₂ + F₂ → 2HF

The oxidation half-reaction is: H₂ → 2H⁺ + 2e^–

The reduction half-reaction is: F₂ + 2e^– → 2F^–

The hydrogen and fluorine ions go on to combine in order to form hydrogen fluoride.

Example 2: Reaction Between Zinc and Copper

This is a type of metal displacement reaction in which copper metal is obtained when zinc displaces the Cu²⁺ion in the copper sulfate solution as shown in the reaction below.

Zn (s) + CuSO₄ (aq) → ZnSO₄ (aq) + Cu (s)

The oxidation half-reaction can be written as: Zn → Zn²⁺ + 2e^–

The reduction half-reaction can be written as: Cu²⁺ + 2e^– → Cu

Redox reaction image 2

Thus, copper is displaced from the copper sulfate solution by zinc in a redox reaction.

Example 3: Reaction between Iron and Hydrogen Peroxide

Fe²⁺ is oxidized to Fe³⁺ by hydrogen peroxide when an acid is present. This reaction is provided below.

2Fe²⁺ + H₂O₂ + 2H⁺ → 2Fe³⁺ + 2H₂O

Oxidation half-reaction: Fe²⁺ → Fe³⁺ + e^–

Reduction half-reaction: H₂O₂ + 2e^– → 2 OH^–

Thus, the hydroxide ion formed from the reduction of hydrogen peroxide combines with the proton donated by the acidic medium to form water.

Oxidation and Reduction Reaction

In order to understand redox reactions, let us first deal with oxidation and reduction reactions individually.

What is Oxidation Reaction?

Oxidation may be defined as loss of electrons from a substance, the other definition of oxidation reactions states that the addition of oxygen or the more electronegative element or removal of hydrogen or the more electropositive element from a substance is called an oxidation reaction.

Following are some examples of oxidation reactions:

2S(s) + O₂ (g) → SO₂ (g) CH₄ (g) + 2O₂ (g) → CO₂ (g) + 2H₂O (l)

What is Reduction Reaction?

Like oxidation reactions, reduction reactions are defined as the gain of electrons. Any substance that gains electron during a chemical reaction gets reduced.

In other forms, the reduction reaction is stated as the addition of hydrogen or more electropositive element or removal of a more electronegative element or oxygen from a substance.

Below are some examples of reduction reactions:

2CH₂CH₂ (g) + H₂ (g) → CH₃CH₃ (g)
2FeCl₃ (aq) + H₂ (g) → 2FeCl₂ (aq) + 2HCl (aq)

Now if we closely examine the above reaction we would find that all the reactions above have both, reduction and oxidation reactions.

The reaction in which FeCl₃ is getting reduced as electronegative element chlorine is being removed from it. While hydrogen is getting oxidized due to the addition of chlorine, an electronegative element, in the same reaction.

Oxidizing and Reducing Agents

The substance (atom, ion, and molecule) that gains electrons and is thereby reduced to a low valency state is called Oxidising agent.
The substance that loses electrons and is thereby oxidised to a higher valency state is called a reducing agent.

Important Oxidizing Agents

Molecules made up of electronegative elements. Eg: O₂, O₃, and X₂ (halogens)
Compounds containing an element that is in the higher oxidized state. Eg: KMnO₄, K₂Cv₂O₇, HNO₃, KClo₃
Oxides of metals and non-metals. Eg: MgO, CuO, CrO₃, P₄O₁₀
Fluorine is the strongest oxidizing agent.

Important Reducing Agents

All metals, for example: Na, Zn, Fe, Al
A few non-metals such as C, Hydrogen, S, P
Hydracids, for example: HCl, HBr, HI, H₂S
Few compounds containing an element in the lower oxidation state. Examples include: FeCl₂, FeSo₄, SnCl₂, Hg₂Cl₂
Metallic hydrides including NaH, LiH, CaH₂, etc.
Organic compound like HCOOH

Lithium is the strongest reducing agent in the solution and Cesium is the strongest reducing agent in the absence of water. The substances which act as oxidizing as well as reducing agents are H₂O₂, SO₂, H₂SO₃, HNO₂, NaNO₂

Reduction Potential of a Half-Reaction

Each of the half-reactions that make up a redox reaction has a standard electrode potential. This potential equals the voltage produced by an electrochemical cell in which the cathode reaction is the half-reaction considered, whereas the anode is a standard hydrogen electrode.

This voltage produced by the half-reactions is called their reduction potentials (denoted by E⁰_red). The value of the reduction potential of a half-reaction is positive for the oxidizing agents that are stronger than H⁺ and negative for the ones that are weaker.

Examples of the reduction potentials of some species are +2.866 V for F₂ and -0.763 V for Zn²⁺.

Identification of Oxidizing and Reducing Agents

If an element is in its higher possible oxidation state in a compound. It can function as an oxidising agent. Eg: KMnO₄, K₂Cr₂O₇, HNO₃, H₂SO₄, HClO₄
If an element is in its possible lower oxidation state in a compound, it can function as a reducing agent. Eg: H₂S, H₂C₂O₄, FeSO₄, SnCl₂
If a highly electronegative element is in its highest oxidation state, the compound will act as an oxidising agent.
If a highly electronegative element is in its lowest oxidation state the compound acts as a reducing agent.

Example: Identify the oxidizing agent and reducing agent in the reactions.

\(\begin{array}{l}2N{{a}_{2}}{{S}_{2}}{{O}_{3}}+{{I}_{2}}\to N{{a}_{2}}{{S}_{4}}{{O}_{6}}+2NaI\end{array} \)
\(\begin{array}{l}2FeC{{l}_{3}}+{{H}_{2}}S\to 2FeC{{l}_{2}}+S+2HCl\end{array} \)
\(\begin{array}{l}3Mg+{{N}_{2}}\to M{{g}_{3}}{{N}_{2}}\end{array} \)
\(\begin{array}{l}AgCN+C{{N}^{-}}\to {{\left[ Ag{{\left( CN \right)}_{2}} \right]}^{-}}\end{array} \)

Solution

Oxidising agent (Species reduced)	Reducing agent (Species oxidised)
I₂	Na₂S₂O₃
FeCl₃	H₂S
N₂	None
None	None

It is not a redox reaction. In each of the following reactions indicate the species oxidised the species reduced, oxidant and reductant

1. Write the skeleton reaction to represent the chemical change
2. With the help of oxidation number of elements find out which element is undergoing oxidation/reduction.
3. Add the electrons on right for oxidation and left for reduction
4. Multiply with suitable integer such that the number of elections taken and lost are the same.

Balancing Redox Reaction

There are two ways of balancing the redox reaction. One method is by using the change in oxidation number of oxidizing agent and the reducing agent and the other method is based on dividing the redox reaction into two half reactions-one of reduction and other oxidation.

Example 1: Write the balanced redox equation when ferrous sulphate is treated with acidified (H₂SO₄) Potassium Permanganate.

Step I

\(\begin{array}{l}KMn{{O}_{4}}+{{H}_{2}}S{{O}_{4}}+FeS{{O}_{4}}\to {{K}_{2}}S{{O}_{4}}+MnS{{O}_{4}}+F{{e}_{2}}{{\left( S{{O}_{4}} \right)}_{3}}+{{H}_{2}}O\end{array} \)

Step II

Thus, here Mn⁺⁷ is reduced to Mn⁺²,

Balancing Redox Reaction by Oxidation State Method

This method is based on the fact that the number of electrons gained during the reduction reaction is equal to the number of electrons lost in oxidation.

Fe²⁺ is oxidised to Fe³⁺ Oxidation:

\(\begin{array}{l}2F{{e}^{2+}}\to Fe_{2}^{+3}+2{{e}^{-}}\end{array} \)

[oxidation]

Reduction:

\(\begin{array}{l}M{{n}^{+7}}+5{{e}^{-}}\to M{{n}^{+2}}\left[ {Re}duciton \right]\end{array} \)

Multiply oxidation reaction with 5 and reduction reaction by 2.

By substituting coefficient

\(\begin{array}{l}2KMn{{O}_{4}}+10FeS{{O}_{4}}+{{H}_{2}}S{{O}_{4}}\to {{K}_{2}}S{{O}_{4}}+5F{{e}_{2}}{{\left( S{{O}_{4}} \right)}_{3}}+2MnS{{O}_{4}}+{{H}_{2}}O\end{array} \)

Balance

\(\begin{array}{l}SO_{4}^{-2}\end{array} \)

by multiplying with 8

⇒

\(\begin{array}{l}2KMn{{O}_{4}}+10FeS{{O}_{4}}+8{{H}_{2}}S{{O}_{4}}\to {{K}_{2}}S{{O}_{4}}+5F{{e}_{2}}{{\left( S{{O}_{4}} \right)}_{3}}+2MnS{{O}_{4}}+8{{H}_{2}}O\end{array} \)

Balancing Redox Reaction by Ion electron Method (Half reaction method)

Steps:

1. Divide the complete reaction into two half-reactions, one representing oxidation and the other representing reduction.
2. First balance other than ‘O’ and ‘H’ atoms.
3. In acidic or neutral medium balance oxygen atoms by adding H₂O molecule and balance H-atoms by adding H⁺ ions.
4. In an alkaline medium, the oxygen atom is balanced by adding H₂O molecule and an equal number of
  \(\begin{array}{l}O{{H}^{\Theta }}\end{array} \)
  ions are added on the opposite side, H⁺ atoms still unbalanced add OH^–
5. Balance the charges by the addition of electrons.
6. Multiply with a suitable integer such that the number of electrons gets cancelled.
7. Add both the half-reactions, similar terms are subtracted and the final equation is written.

Problems on Balancing Redox Reactions

Example 1: Balance the following redox reaction in the acid medium by the ion-electron method.

Redox reaction image 3

Reduction half-reaction

\(\begin{array}{l}MnO_{4}^{-}\to M{{n}^{+2}}\end{array} \)

[Balance other than ‘O’ and H]

\(\begin{array}{l}MnO_{4}^{-}\to M{{n}^{+2}}+4{{H}_{2}}O\end{array} \)

[O atoms are balanced]

\(\begin{array}{l}MnO_{4}^{-}+8{{H}^{+}}\to M{{n}^{+2}}+4{{H}_{2}}O\end{array} \)

[H atoms are balanced]

\(\begin{array}{l}MnO_{4}^{-}+8{{H}^{+}}+5{{e}^{-}}\to M{{n}^{+2}}+4{{H}_{2}}O\end{array} \)

[Charges are balanced]

2×

\(\begin{array}{l}[MnO_{4}^{-}+8{{H}^{+}}+5{{e}^{-}}\to M{{n}^{+2}}+4{{H}_{2}}O]\end{array} \)

\(\begin{array}{l}[2MnO_{4}^{-}+16{{H}^{+}}+10{{e}^{-}}\to 2M{{n}^{+2}}+8{{H}_{2}}O]\end{array} \)

Oxidation half reaction

\(\begin{array}{l}{{I}^{-}}\to {{I}_{2}}\end{array} \)

\(\begin{array}{l}2{{I}^{-}}\to {{I}_{2}}\end{array} \)

\(\begin{array}{l}2{{I}^{-}}\to {{I}_{2}}+2{{e}^{-}}\end{array} \)

5×[

\(\begin{array}{l}2{{I}^{-}}\to {{I}_{2}}+2{{e}^{-}}\end{array} \)

]

\(\begin{array}{l}10{{I}^{-}}\to 5{{I}_{2}}+10{{e}^{-}}\end{array} \)

\(\begin{array}{l}\overline{\underline{2MnO_{4}^{-}+16{{H}^{+}}+10{{I}^{-}}\to 2m{{n}^{+2}}+5{{I}_{2}}+8{{H}_{2}}O}}\end{array} \)

Example 2: Balance the following redox reaction in acid medium by ion-electron method.

Redox reaction image 4

Reduction Half Reaction

\(\begin{array}{l}C{{r}_{2}}O_{7}^{-2}\to C{{r}^{+3}}\end{array} \)
\(\begin{array}{l}C{{r}_{2}}O_{7}^{-2}\to 2C{{r}^{+3}}\end{array} \)
\(\begin{array}{l}C{{r}_{2}}O_{7}^{-2}\to 2C{{r}^{+3}}+7{{H}_{2}}O\end{array} \)
.
\(\begin{array}{l}C{{r}_{2}}O_{7}^{-2}+14{{H}^{+}}\to 2C{{r}^{+3}}+7{{H}_{2}}O\end{array} \)
\(\begin{array}{l}C{{r}_{2}}O_{7}^{-2}+14{{H}^{+}}6{{e}^{-}}\to 2C{{r}^{+3}}+7{{H}_{2}}O\end{array} \)

Oxidation Half Reaction

\(\begin{array}{l}SO_{3}^{-2}\to SO_{4}^{-2}\end{array} \)
\(\begin{array}{l}SO_{3}^{-2}+{{H}_{2}}O\to SO_{4}^{-2}\end{array} \)
\(\begin{array}{l}SO_{3}^{-2}+{{H}_{2}}O\to SO_{4}^{-2}+2H^{+}\end{array} \)
\(\begin{array}{l}\left[ SO_{3}^{-2}+{{H}_{2}}O\to SO_{4}^{-2}+2{{H}^{+}}+2e \right]\times 3\end{array} \)
\(\begin{array}{l}3SO_{3}^{-2}+3{{H}_{2}}O\to 3SO_{4}^{-2}+6{{H}^{+}}+6{{e}^{-}}\end{array} \)
\(\begin{array}{l}\left[ C{{r}_{2}}O_{7}^{-2}+14{{H}^{+}}6{{e}^{-}}\to 2C{{r}^{+3}}+7{{H}_{2}}O \right]\end{array} \)

\(\begin{array}{l}C{{r}_{2}}O_{7}^{-2}+14{{H}^{+}}+{6{{e}^{-}}}\to 2C{{r}^{+3}}+7{{H}_{2}}O\end{array} \)

\(\begin{array}{l}3SO_{3}^{-2}+3{{H}_{2}}O\to 3SO_{4}^{-2}+6{{H}^{+}}+{6{{e}^{-}}}\end{array} \)

\(\begin{array}{l}\overline{\underline{C{{r}_{2}}O_{7}^{-2}+3SO_{3}^{-2}\to 2C{{r}^{+3}}+3SO_{4}^{-2}+4{{H}_{2}}O+8{{H}^{+}}}}\end{array} \)

Example: 3 Balance the following reaction in basic medium by ion-electron method.

Redox reaction image 5

\(\begin{array}{l}{{P}_{4}}\rightarrow{O{{H}^{-}}}P{{H}_{3}}+{{H}_{2}}PO_{2}^{-}\end{array} \)

Reduction Half Reaction

\(\begin{array}{l}{{P}_{4}}\rightarrow{{}}P{{H}_{3}}\end{array} \)
\(\begin{array}{l}{{P}_{4}}\rightarrow{{}}4P{{H}_{3}}\end{array} \)
\(\begin{array}{l}{{P}_{4}}+12{{H}_{2}}O\rightarrow{{}}4P{{H}_{3}}+12O{{H}^{\Theta }}\end{array} \)
\(\begin{array}{l}\left[ {{P}_{4}}+12{{H}_{2}}O+12{{e}^{-}}\rightarrow{{}}4P{{H}_{3}}+12O{{H}^{\Theta }} \right]\times 1\end{array} \)

Oxidation Half Reaction

\(\begin{array}{l}{{P}_{4}}\rightarrow{{}}{{H}_{2}}PO_{2}^{-}\end{array} \)
\(\begin{array}{l}{{P}_{4}}\rightarrow{{}}4{{H}_{2}}PO_{2}^{-}\end{array} \)
\(\begin{array}{l}{{P}_{4}}+8{{H}_{2}}O\rightarrow{{}}4{{H}_{2}}PO_{2}^{-}+8O{{H}^{\Theta }}+8{{H}_{2}}O\end{array} \)
\(\begin{array}{l}\left[ {{P}_{4}}+8{{H}_{2}}O+8O{{H}^{-}}\rightarrow{{}}4{{H}_{2}}PO_{2}^{-}+4{{e}^{-}}+8{{H}_{2}}O \right]\times 3\end{array} \)

\(\begin{array}{l}3{{P}_{4}}+{24{{H}_{2}}O}+24O{{H}^{-}}\rightarrow{{}}12{{H}_{2}}PO_{2}^{-}+{12{{e}^{-}}}+{24{{H}_{2}}O}\end{array} \)

Applications of Redox Reaction

Redox reactions have numerous industrial and everyday applications. A few of these applications of redox reactions are listed below.

Applications of Redox Reaction in Electrochemistry

The battery used for generating DC current uses a redox reaction to produce electrical energy. Redox reaction image 6

Batteries or electrochemical cells used in our day-to-day life are also based on redox reactions. For example, storage cells are used in vehicles to supply all the electrical needs of the vehicles.

Redox Reaction in Combustion

Combustion is a type of oxidation-reduction reaction and hence it is a redox reaction. An explosion is a fast form of combustion and hence explosion can be treated as a redox reaction. Even the space shuttle uses redox reactions. The combination of ammonium perchlorate and powdered aluminium inside the rocket boosters gives rise to an oxidation-reduction reaction.

Applications in Photosynthesis

Green plants convert water and carbon dioxide into carbohydrates and this process is defined as photosynthesis. The reaction is given as 6CO2 + 6H2O → C6H12O6 + 6O2

Redox reaction image 7

In the above reaction, we can see that carbon dioxide is reduced to carbohydrates while the water gets oxidized to oxygen and hence it is a redox reaction. The energy is provided by the sunlight for this reaction. This reaction is a source of food for animals and plants.

Real-Life Uses of Redox Reaction

Production of some important chemicals is also based on electrolysis which in turn is based on redox reactions. Many chemicals like caustic soda, chlorine, etc. are produced using redox reactions.
Oxidation-Reduction reactions also find their application in sanitizing water and bleaching materials.
The surfaces of many metals can be protected from corrosion by connecting them to sacrificial anodes which undergoes corrosion instead. A common example of this technique is the galvanization of steel.
The industrial production of cleaning products involves the oxidation process.
Nitric acid, a component of many fertilizers, is produced from the oxidation reaction of ammonia.
Electroplating is a process that uses redox reactions to apply a thin coating of a material on an object. Electroplating is used in the production of gold-plated jewellery.
Many metals are separated from their ores with the help of redox reactions. One such example is the smelting of metal sulfides in the presence of reducing agents.

The main source of oxidation is oxygen and therefore redox reaction or oxidation-reduction reactions are responsible for food spoilage.

Frequently Asked Questions On Redox Reactions

What are oxidation-reduction reactions?

Oxidation-reduction reactions are chemical reactions that involve the transfer of electrons between the reacting species. These electron transfers are accompanied by a change in the oxidation state of the reactants.

What are oxidizing agents?

An oxidizing agent is an electron-accepting species that is readily reduced in an oxidation-reduction reaction. The oxidation numbers of these species tend to decrease in redox reactions. Examples: nitric acid (HNO₃) and hydrogen peroxide (H₂O₂).

What are reducing agents?

Reducing agents are the electron-donating species that readily undergo oxidation in oxidation-reduction reactions. These species tend to lose electrons in redox reactions and their oxidation number increases. Examples: zinc and lithium.

How to determine if a redox reaction has occurred?

1. First, assign the oxidation numbers to all the atoms.

2. Compare the oxidation numbers from the reactant side to the product side.

3. In the case of a redox reaction, the oxidation numbers of two elements change from the reactant side to the product side.

Element Oxidized: The one whose oxidation number is increased.
Element Reduced: The one whose oxidation number is decreased.

Why is the reaction between hydrogen and fluorine a redox reaction?

In this reaction, the H2 molecule loses its electrons, yielding two protons. The electrons are accepted by the F2 molecule and it leads to the formation of two fluoride ions. Now a polar covalent bond is formed between the fluoride ion and the proton. Thus, this reaction is redox.

Is every chemical reaction a redox reaction?

No, not every chemical reaction is a redox reaction. Reactions like double decompositions, acid-base neutralization reactions, precipitation reactions are non-redox reactions.

Na₂SO₄ + BaCl₂ = 2NaCl + BaSO₄
2KI + Pb(NO3)₂ = 2KNO₃ + PbI₂
2HCl + CaCO₃ = H₂O + CaCl₂ + CO₂
HNO₃ + NaOH = H₂O + NaNO₃

Some decomposition reactions are also non-redox reactions:

NH₄Cl = HCl + NH₃
CaCO₃ = CO₂ + CaO
2Al(OH)₃ = 3H₂O + Al2O₃

Redox Reactions