2.1 Concept of Oxidation and Reduction

Redox reactions involve two complementary processes: oxidation (loss of electrons) and reduction (gain of electrons). These processes always occur simultaneously because electrons released by one species must be accepted by another. Traditionally, oxidation was understood as the addition of oxygen or removal of hydrogen, while reduction was described as the removal of oxygen or addition of hydrogen. The modern definition relies on electron transfer and oxidation-number changes.

2.2 Oxidation Number and Its Significance

Oxidation number (or oxidation state) is an assigned value used to track electron movement during chemical reactions. It helps identify which species is oxidised or reduced. An increase in oxidation number indicates oxidation, while a decrease indicates reduction. Rules for assigning oxidation numbers allow for a systematic approach to balancing redox equations.

2.3 Reducing and Oxidising Agents

The substance that donates electrons and undergoes oxidation is called a reducing agent. Conversely, the substance that accepts electrons and undergoes reduction is known as an oxidising agent. Both agents are essential since redox reactions cannot occur without electron transfer between the two.

2.4 Balancing Redox Reactions

Redox reactions must be balanced not only for atoms but also for the charge. Two methods are commonly used:

• Oxidation Number Method
• Ion–Electron (Half-Reaction) Method These methods ensure that electrons lost in oxidation equal electrons gained in reduction.

2.5 Electrode Processes

Electrode processes occur at the surfaces of electrodes in electrochemical cells. Electrodes are classified into:

• Anode: where oxidation occurs and electrons are released.
• Cathode: where reduction occurs and electrons are consumed.

In a galvanic (voltaic) cell, chemical energy is converted into electrical energy. The anode is negative, and electrons flow from anode to cathode through an external circuit. 

• Begin by understanding that when a zinc rod is dipped in copper sulphate solution, a redox reaction occurs directly:
  – Zinc is oxidised to Zn²⁺
  – Copper ions (Cu²⁺) are reduced to copper metal
  – This direct electron transfer also releases heat.

• To make the electron transfer occur indirectly, modify the setup by separating the oxidising and reducing agents:

• Place CuSO₄ solution with a copper rod in one beaker.
• Place ZnSO₄ solution with a zinc rod in another beaker.

• In each beaker, both the oxidised and reduced forms of a species are present.
• These combinations form redox couples, represented as: Zn²⁺/Zn and Cu²⁺/Cu

• A redox couple is written with the oxidised form first, separated from the reduced form by a vertical line/slash, representing the interface (solid/solution).
• Connect the two beakers using a salt bridge (e.g., KCl or NH₄NO₃ in agar-agar gel).

• The salt bridge allows ionic movement to maintain electrical neutrality without mixing the solutions.
• Join the zinc and copper rods using a metallic wire equipped with an ammeter and switch.

• This complete setup is known as the Daniell cell.
• When the switch is off, no reaction or current flow occurs.
• When the switch is on, the following observations must be noted:

• Electrons flow through the external wire from the zinc rod to the copper rod.
• Ions migrate through the salt bridge, enabling the flow of electricity between the solutions.

• The potential difference generated between the metal rods is known as the electrode potential of each electrode.
• When all reacting species are at unit concentration, gases at 1 atm, and temperature at 298 K, the electrode potential is called the Standard Electrode Potential (E°).

• By convention, E°(H⁺/H₂) = 0.00 V.

• The sign of E° helps determine the nature of the redox couple:
• Negative E° → stronger reducing agent than H⁺/H₂.
• Positive E° → weaker reducing agent than H⁺/H₂.

• Standard electrode potentials provide valuable information for predicting and analysing redox reactions.            

2.6 Salt Bridge and Its Function

A salt bridge connects the two half-cells of an electrochemical cell, maintaining electrical neutrality. It allows ions—not electrons—to move between solutions, preventing charge buildup that would otherwise stop the reaction.

2.7 Applications of Redox and Electrode Processes

Redox reactions play a vital role in diverse fields such as metallurgy, corrosion control, energy storage (batteries), fuel cells, and biological systems. Electrode processes form the basis for technologies like electroplating, purification of metals, and electrolysis of compounds.