16.3. Colligative Properties http://www.ck12.orgmolesC 12 H 10 = 5 .00 g C 12 H 10 × 154 1 mol C.22 g C^1212 HH^1010 = 0 .0324 mol C 12 H 10molesC 10 H 8 = 7 .50 g C 10 H 8 × 128 1 mol C.18 g C^1010 HH^88 = 0 .0585 mol C 10 H 8mass of benzene= 200 .0 g benzene×1000 g1 kg = 0 .2000 kg benzenemolality=^0 .0324 mol C 0 .2000 kg benzene^12 H^10 +^0 .0585 mol C^10 H^8 = 0. 455 m
∆Tf= 5. 12 ◦C/m× 0. 455 m× 1 = 2. 33 ◦C
The freezing point will be lowered by 2.33 °C. Subtracting this from the normal freezing point of benzene (5.5 °C),
this solution will freeze at 3.2 °C.
Values of kfand kbfor some other common solvents are listed in theTable16.3.TABLE16.3: Molal Boiling-Point Elevation and Freezing-Point Depression Constants of Several
Common Liquids
Solvent Normal Freezing
Point (°C)kf(°C/m) Normal Boiling
Point (°C)kb(°C/m)Water 0 1.86 100 0.52
Benzene 5.5 5.12 80.1 2.53
Ethanol -117.3 1.99 78.4 1.22
Acetic Acid 16.6 3.90 117.9 2.93
Cyclohexane 6.6 20.0 80.7 2.79Notice that kfis generally larger than kbfor a given substance.Lesson Summary
- The degree to which particles of a given liquid tend to escape into the gas phase is measured by the liquid’s
vapor pressure. The vapor pressure of a solution is a colligative property, which means that it is affected only
by the concentration of solute particles and not their identity. - The vapor pressure of a solution is lower than the vapor pressure of the pure solvent (P <P°).
- Raoult’s Law states that the vapor pressure of a solution is equal to the product of the vapor pressure of the
pure solvent and the mole fraction of the solvent (P =χsolventP°). - The mole fraction of a component in a mixture (χ) can be calculated by dividing the number of particles (or
moles) of the component by the total number of particles (or moles) in the complete mixture. - Adding a solute increases the boiling point of a pure solvent. This change can be calculated using the equation
∆Tb=kb×m×i. - Similarly, adding a solute decreases the freezing point of a pure solvent. This change can be calculated using
the equation∆Tf=kf×m×i.
Review Problems
- Would you expect water or ethanol (C 2 H 5 OH) to have a higher vapor pressure at a given temperature?
- Based onFigure16.11, which substance do you suppose has the strongest intermolecular attractions? Which
has the weakest intermolecular attractions? Which substance would evaporate most quickly? - What would be the vapor pressure of a 1.0 molal NaCl solution?