c12 JWBS043-Rogers September 13, 2010 11:27 Printer Name: Yet to Come
190 SOLUTION CHEMISTRY
dT≈Tbto restore the system to its original vapor pressure. These small changes
are related by the equation
p
p
=
vapH
R
(
1
T^2
)
Tb
where we have already shown thatp=p◦ 1 X 2 sop/p=X 2 p◦ 1 /p. For experiments
carried out at atmospheric pressure,p◦ 1 is the vapor pressure at the normal boiling point
of the pure solvent. The differencep=p−p◦ 1 is thevapor pressure depression.
The temperature riseTbnecessary to restorepto its original value is theboiling
point elevation.
In the limit of small amounts of solute, the vapor pressure change from that of the
pure solvent is small,p 1 ◦≈p, so they cancel to a good approximation and
X 2 p◦A
p
≈X 2 ≈
vapH
R
(
1
T^2
)
Tb
or
Tb≈
RTb^2 X 2
vapH 1
Writing outX 2 intermsofgramsandmolarmassofthesolventM 1 (problems) leads
to the boiling point elevation in practical laboratory terms as
Tb≈
RTb^2 M 1
vapH 1 · 1000
m=Kbm
whereKbis called theboiling point constantor sometimes theebullioscopicconstant.
The molality,m, is the number of moles per 1000 g of solvent, and M 1 is the molar
mass of the solvent; that is, we are expressing the amount of solute in units of
molality. Typical values forKbrange from about 0.5 to 5 K kg mol−^1 ; for example,
Kb(water)= 0 .51 K kg mol−^1 andKb(benzene)= 2 .53 K kg mol−^1.
As we have seen,Kb is derived through Gibbs chemical potentials. A simi-
lar treatment leads to thefreezing point depressionTf and the freezing point
constantKf:
Tf≈
RTf^2 M 1
freezHA· 1000
m=Kfm
wherefreezHAis the enthalpy of freezing of the pure solvent at 1 atm. Typical
values areKf(water)= 1 .86 K kg mol−^1 (that famous number we memorized in
elementary chemistry) andKf(benzene)= 5 .07 K kg mol−^1. If we measure the