COLLIGATIVE PROPERTIES
Purpose
The purpose of this experiment is to
investigate colligative properties of solutions and how they can be used to
determine molecular weight of solute.
Discussion
From the Clausius-Clapeyron equation,
(1)
the vapor pressure of a solution of a
non-volatile solute may be compared to that of the pure solvent. It can be shown that the boiling point
elevation is
(2)
where 
is the boiling point
of the solvent, 
is molecular weight of
solvent, 
is heat of vaporization of solvent, and m is the molal concentration.
This equation is valid for ideal solutions and for small temperature
changes.
The equation may be rewritten as
(3)
where 
is the molal boiling
point constant. Since the molal
concentration is
(4)
where,
,
,
Combining both equations the molecular
weight of the solute is
(5)
Analogous equations may be derived for
freezing point depression.
(6)
(7)
Values of and 
are best determined
experimentally, but may be determined from equation 2, as presented in the
following table:
|
Solvent |
B.P. (°C) |
(°C / molal) |
M.P. (°C) |
(°C / molal) |
|
Water |
100.0° |
0.52 |
0.0° |
1.86 |
|
Benzene |
80.2° |
2.53 |
5.50° |
5.12 |
|
Carbon Tetrachloride |
76.6° |
5.03 |
|
|
|
Camphor |
|
|
178.0° |
37.7 |
|
Cyclohexane |
|
|
6.6° |
20.4 |
Equipment
and Chemicals
Boiling
Point:
Cottrell
boiling point apparatus, Beckman
thermometer, micro-burner, solvent (CC14),
naphthalene, other solute (“unknown”, diphenyl, benzoic acid, salicylic acid, p-nitrotoluene.
Melting
Point:
Beckman
freezing point apparatus, Beckman thermometer, cyclohexane, naphthalene, other solute
(“unknown”, such as p-dichlorobenzene, biphenyl, p- bromochlorobenzene).
Directions
Boiling
Point:
1. Pipet 75 ml CCl4, with a bulb,
into the apparatus.
2. Insert
Beckman thermometer. Note: this is a special thermometer with a six
degree range. Each division is 0.01°. The mercury in the reservoir may be varied to
coincide with the desired temperature.
Thus, absolute temperatures are not measured, only temperature changes. A hand lens may be used to facilitate reading
the thermometer.
3. .Boil
solvent gently and determine boiling point.
The thermometer bulb must be in contact with the boiling solution, not
the condensing vapor which is pure solvent.
Take several readings, which should agree with ± 0.003°.
4. Add an
amount of naphthalene which will give a 1-2° temperature change. Measure the boiling point as before. (Use pellet press to facilitate sample
handling.)
5. Add
another quantity of naphthalene and again determine the boiling point.
6. From the
data determine two values of and the average . (Use a rearranged
equation 5.)
7. Pour
solution into waste solvent bottle, not the drain.
8. Repeat
steps 1 - 5 with an “unknown” instead of naphthalene.
9. Determine
average molecular weight of “unknown”.
Use equation 5.
Directions
Melting
Point
1. Pipet 20 ml (to nearest 0.01 ml) cyclohexane into apparatus.
2. Place tube
in larger test tube (air jacket) which is submerged in ice bath. Freezing
point of cyclohexane is measured with Beckmann thermometer to nearest
0.002° on a cooling cycle. Melt and repeat.
3. Dissolve
about 0.03 g (measured to ± 0.0001 g)
naphthalene. To determine melting point,
the solution is frozen to a slurry, the test tube is placed in the air jacket,
and the solution is allowed to warm to several degrees above the melting
point. Record the temperature at 30
second intervals. Plot temperature vs.
time. The melting point is the
intersection of the two straight-line portions of the curve. Repeat until melting points differ by no more
than 5%.
4. Add
another quantity of naphthalene and again determine melting point.
5. From the
data determine .
6. Pour
solution into waste solvent bottle, not
the sink.
7. Repeat
steps 1 - 4 with an “unknown” instead of naphthalene.
8. Determine
molecular weight of “unknown”.
Molecular
Weight Apparatus-Boiling Point, Cottrell-Choppin, T. Grindings, PYREX Brand
Glass.
Basic Cottrell design, but of heavy
construction with separate pump, reducing fragility and a three way stopcock
permitting the withdrawal of samples from boiling tube or condenser or the
return of condensate to the vessel. For
technique, refer to “Journal of Chemical Education,” 24, 491 (1947). For thermometer with T grinding, see
S-62004. For condenser, see
S-22530-B. T grindings, outer part, No.
19/38 are provided to receive thermometer and condenser. The inner and outer elements are joined by a
T grinding No. 45/50. Overall height,
310 mm: overall width, 115 mm.
|
|
Molecular
Weight Apparatus- Freezing Point, Beckmann
Improved form, intended for use of
sample pellets prepared in presses.
Consists of a freezing point tube, 190 mm by 25 mm, with a side
tubulature for the introduction of pellets, tub being supported by a rubber
stopper in an air jacket tube 150 x 37 mm
which rests in a corresponding hole in a nickel plated brass cover fitted to a
glass freezing job, S-43725-D.
The freezing point tube is equipped
with stopper through which are inserted a Beckmann thermometer and a chromel
wire stirrer, the latter operating through a small piece of glass tubing
inserted in the stopper. The internal
stirrer is finished in a ring form agitating end which moves vertically within
the freezing point tube and is so adjusted as to clear the Beckmann thermometer
bulb when located in the center of the tube.
Thermometer-Beckmann
Differential, Upward Scale
For accurate measurements of very small
temperature differentials such as those encountered in boiling point
determinations and calorimeter measurements.
The range covers approximately 5°C graduated in 1/100 subdivisions. Has a mercury reservoir with auxiliary scale
providing a rough indication of the amount of mercury to be trapped in the
reservoir to provide the desired operating range. A dropping trap is included. This instrument can be used only for
determining temperature differences.
Thermometer-Beckmann
Differential, Downward Scale
Similar to the 14-5905 Thermometer, but
for measurement of small differentials in freezing point and molecular weight
determinations, and with scale reading downward. Subdivided to 1/100°.