Solutions

1. Introduction

A solution is a homogeneous mixture of two or more substances. This chapter covers the physical chemistry of solutions — how solute particles affect the properties of the solvent.

2. Concentration Terms

Molarity (M): moles of solute per litre of solution. Varies with temperature. Molality (m): moles of solute per kg of solvent. Independent of temperature. Mole fraction (x): ratio of moles of one component to total moles. Mass percentage: (mass of solute/mass of solution) × 100%.

3. Raoult's Law

For a volatile solute: P_A = x_A P_A⁰, where P_A⁰ is the vapour pressure of pure A.

For a non-volatile solute: P_solution = x_solvent P_solvent⁰.

Lowering of vapour pressure: ΔP = P⁰ - P = x_solute P⁰.

3.1 Ideal and Non-Ideal Solutions

Ideal solutions: Obey Raoult's law at all concentrations. ΔH_mix = 0, ΔV_mix = 0. Example: Benzene + Toluene, n-Hexane + n-Heptane.

Non-ideal solutions: Deviate from Raoult's law. Positive deviation (A-B interactions weaker): ΔH_mix > 0, ΔV_mix > 0. Example: Ethanol + Acetone. Negative deviation (A-B interactions stronger): ΔH_mix < 0, ΔV_mix < 0. Example: Acetone + Chloroform.

4. Colligative Properties

Properties that depend only on the number of solute particles, not their nature.

4.1 Relative Lowering of Vapour Pressure

(P⁰ - P)/P⁰ = x_solute = n/(n + N)

4.2 Elevation of Boiling Point

ΔT_b = K_b × m, where K_b is the ebullioscopic constant.

4.3 Depression of Freezing Point

ΔT_f = K_f × m, where K_f is the cryoscopic constant.

4.4 Osmotic Pressure

π = iCRT (for van't Hoff equation).

Osmosis: net flow of solvent from lower to higher concentration through a semipermeable membrane.

5. Determination of Molar Mass Using Colligative Properties

5.1 From Elevation of Boiling Point

Molar mass M = (K_b × w₂ × 1000)/(ΔT_b × w₁) where w₂ = mass of solute (g), w₁ = mass of solvent (g).

5.2 From Depression of Freezing Point

M = (K_f × w₂ × 1000)/(ΔT_f × w₁)

5.3 From Osmotic Pressure

M = (w₂RT)/(πV)

'Osmotic pressure method is the most accurate for determining molar masses of macromolecules because the osmotic pressure is measurable even for very dilute solutions.'

6. Abnormal Molar Masses

When a solute dissociates or associates in solution, the observed molar mass differs from the expected molar mass.

Dissociation: Observed M < Calculated M (more particles, greater colligative effect). i = Calculated M/Observed M.

Association: Observed M > Calculated M (fewer particles, smaller colligative effect). i = Calculated M/Observed M.

6.1 Degree of Dissociation

For dissociation of AₙBₘ → nA + mB: α = (i - 1)/((n + m) - 1)

6.2 Degree of Association

For association of n molecules of A: α = (1 - i)/(1 - 1/n)

7. Van't Hoff Factor

i = (observed colligative property)/(calculated colligative property).

i = 1 + (n - 1)α, where α is the degree of dissociation/association.

'For dissociation, i > 1. For association, i < 1. For non-electrolytes, i = 1.'

6. Worked Problems

Problem 1: Calculate the boiling point of a solution containing 18 g of glucose (C₆H₁₂O₆) in 100 g of water. K_b for water = 0.52 K kg/mol. Solution: Moles of glucose = 18/180 = 0.1 mol. m = 0.1/0.1 = 1 mol/kg. ΔT_b = 0.52 × 1 = 0.52°C. Boiling point = 100 + 0.52 = 100.52°C.

Problem 2: The freezing point of a 0.1 m solution of NaCl is -0.372°C. K_f for water = 1.86 K kg/mol. Find i. Solution: ΔT_f observed = 0.372. ΔT_f calculated = 1.86 × 0.1 = 0.186. i = 0.372/0.186 = 2. NaCl dissociates into Na⁺ and Cl⁻, giving i ≈ 2.

7. Common Mistakes

'Students often forget that molarity depends on temperature while molality does not. For colligative property calculations, use molality (not molarity).'

8. ISC Exam Focus

TopicTheory MarksPractical Marks
Concentration terms22
Raoult's law31
Colligative properties53
Van't Hoff factor32

9. Self-Test Questions

  1. Define the term 'colligative property'. Name four colligative properties.
  2. 10 g of a non-volatile solute dissolved in 200 g of benzene raises its boiling point by 1°C. K_b of benzene = 2.53 K kg/mol. Find molar mass.
  3. Calculate the osmotic pressure of 0.1 M glucose solution at 27°C (R = 0.0821 L atm/mol K).
  4. Explain positive and negative deviations from Raoult's law with examples.
  5. The freezing point of 0.1 m acetic acid solution is -0.188°C. K_f = 1.86. Calculate the degree of dissociation of acetic acid.
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