298 6 The Thermodynamics of SolutionsSolutionΠ(0.200 mol L−^1 )(
1000 L
1m−^3)(
8 .3145 J K−^1 mol−^1)
(298.15 K) 4. 96 × 105 Pa 4 .89 atmExercise 6.36
a.Verify Eq. (6.7-23).
b.Find the osmotic pressure of a solution of 5.00 g of glucose in 1.000 L of aqueous solution at
298.15 K.
c.Calculate the height of the solution required to give a hydrostatic pressure of this size. The
density of the solution is 1.002 g cm−^3.PROBLEMS
Section 6.7: Colligative Properties
6.62 The normal melting temperature of phenanthrene is
96.3◦C. Its enthalpy change of fusion is 18.6 kJ mol−^1.
Find the solubility (maximum mole fraction) of
phenanthrene in a liquid solution with naphthalene at
82.0◦C. Assume that the liquid solution is ideal and that no
solid solubility occurs.
6.63 The melting temperature of TNT (2,4,6-trinitrotoluene)
is 80.83◦C, and its enthalpy change of fusion is
21.23 kJ mol−^1. Assume that TNT forms an ideal liquid
solution with nitrobenzene. Find the maximum solubility
(mole fraction of TNT in the liquid at equilibrium with
solid TNT) at 60◦C. Assume that the liquid solution is
ideal and that no solid solubility occurs. What can you say
about the maximum solubility of TNT in some other liquid
with which TNT forms an ideal solution?
6.64 a.Calculate the freezing temperature at 1.000 atm of a
solution of 5.00 g of sucrose in 95.00 g of water, using
Eq. (6.7-9).
b.Calculate the freezing temperature of the solution of
part a using Eq. (6.7-7).c.Modify Eq. (6.7-7) by discontinuing the assumption
that the solution is dilute, including an activity
coefficient for the water. From the actual freezing point
depression of 0.29◦C, find the value of the activity
coefficient of water in the solution of part a.6.65 Find the freezing point depression of a solution of 1.500 g
of KCl in 1.000 kg of water. Assume that the KCl
dissociates completely, so that 2 mol of dissolved ions
results from 1 mol of KCl.
6.66A sample of 1.000 g of a solute is dissolved in 15.00 mL of
benzene at 20◦C. The density of benzene at this
temperature is 0.8765 g mL−^1. The freezing temperature
depression was 3.04◦C. Find the molar mass of
the solute.6.67 a.Calculate the boiling temperature of the solution of
Problem 6.64, using Eq. (6.7-14).b.Repeat the calculation using Eq. (6.7-15) and calculate
the percent difference of the boiling point elevation
from that of part a.c.Repeat the calculation using Eq. (6.7-16) and calculate
the difference of the boiling point elevation from that
of part a.6.68 The density of ethylene glycol is 1.1088 g cm−^3 and its
melting temperature is equal to− 11. 5 ◦C. Calculate the
freezing temperature of a mixture of 0.500 L of ethylene
glycol and 9.500 L of water.
6.69A sample of myoglobin with mass 1.000 g is dissolved in
100.0 mL of aqueous solution. The osmotic pressure of the
solution is 11.0 torr at 25.00◦C. Find the molar mass of
myoglobin.