It is the state when the rate of forward and backward reactions become equal and the concentrations of reactants and products remain constant in a closed system.

Reversible reactions can proceed in both directions (e.g., Haber process). Irreversible reactions proceed only in one direction (e.g., burning of coal).

N₂(g) + 3H₂(g) ⇌ 2NH₃(g). Industrial conditions: iron catalyst, high pressure (∼150–300 atm), moderate temperature (400–500 °C).

Because both forward and backward reactions continue to occur at equal rates; molecules are still reacting though the overall concentrations remain constant.

Increasing temperature shifts the equilibrium toward the reactants (left) for an exothermic reaction, reducing product yield. Lowering temperature favors product formation (right).

Homogeneous: N₂(g) + 3H₂(g) ⇌ 2NH₃(g). Heterogeneous: CaCO₃(s) ⇌ CaO(s) + CO₂(g).

• Equilibrium is reached only in a closed system.
• It is a dynamic state where forward and backward rates are equal.
• Concentrations of reactants and products remain constant (but not necessarily equal).
• Equilibrium position can be shifted by changing concentration, pressure (for gases), or temperature.
• Catalysts speed up equilibrium attainment but do not change equilibrium position.

Principle: If a system at equilibrium is disturbed by change in concentration, pressure or temperature, it shifts to minimize the disturbance.

Examples:

• Concentration: In N₂ + 3H₂ ⇌ 2NH₃, adding more H₂ shifts equilibrium right to produce more NH₃.
• Pressure: For gases, increasing pressure favors the side with fewer moles. In Haber process (4 mol gas → 2 mol gas), higher pressure favors ammonia (products).
• Temperature: For exothermic reactions (heat as product), raising temperature shifts equilibrium left (toward reactants).

1. Concentration: Changing concentration shifts the position to oppose the change.
2. Pressure: Affects equilibria involving gases; increase in pressure favors fewer gas moles.
3. Temperature: Changes equilibrium constant; increasing temperature favors endothermic direction.
4. Catalyst: Increases rate of both forward and backward reactions equally; no change in equilibrium composition.

Haber process: N₂ + 3H₂ ⇌ 2NH₃. Produces ammonia for fertilizers. Optimized by moderate temperature, high pressure and iron catalyst to balance rate and yield.

Contact process (summary): For H₂SO₄ manufacture — SO₂ → SO₃ (catalysed by V₂O₅) then converted to H₂SO₄. Equilibrium and conditions are chosen for best yield and rate.

Homogeneous: All reactants and products are in the same phase (e.g., all gases).
Heterogeneous: Reactants/products are in different phases (e.g., solid + gas). Solids and pure liquids do not appear in the expression for K_c.