10.4 Transport Processes in Liquids 473
Equation (10.4-4) allows us to expressfin terms ofD 2 , the diffusion coefficient
of the macromolecular substance, giving
M 2
RTS
D 2 ( 1 −ρ 1 /ρ 2 )
(10.4-13)
where we have replacedkBNAvby the ideal gas constantR. This equation has been
widely used to obtain molar masses of proteins. It is possible to get values of bothSand
D 2 from the same experiment if a concentration profile similar to that of Figure 10.4
can be observed.
EXAMPLE10.19
The sedimentation coefficient of a sample of human hemoglobin in water is equal to 4.48
svedberg at 20◦C, and its density is 1.335 g mL−^1. The density of water at this temperature
is equal to 0.998 g mL−^1. Use the value of the diffusion coefficient from Example 10.16 to
determine the molar mass of hemoglobin.
Solution
M
(
8 .3145 J K−^1 mol−^1
)
( 293 .15 K)
(
4. 48 × 10 −^13 s
)
(
6. 9 × 10 −^11 m^2 s−^1
)(
1 −
0. 998
1. 335
)
63 J m−^2 s^2 mol−^1 63 kg mol−^1
The actual molar mass is 68 kg mol−^1.
Exercise 10.17
Assume that an ultracentrifuge rotor is rotating at 1. 00 × 105 revolutions per second and that
hemoglobin molecules in aqueous solution at 20◦C are 12.0 cm from the axis of rotation.
a.Find the sedimentation speed. Find the mean distance sedimented by the molecules in
10.0 minutes.
b.Find the root-mean-square distance in one direction diffused by hemoglobin molecules in
this temperature in 10.00 minutes.
PROBLEMS
Section 10.4: Transport Processes in Liquids
10.34A lead BB (a spherical projectile) is falling at a steady
speed in glycerol at 20◦C. Find its speed. The diameter of
the BB is 0.177 inch, and the density of lead is
11.35 g cm−^3.
10.35The following are data for the viscosity of benzene, with
the viscosity in centipoise (1 poise1gcm−^1 s−^1 ).
T/K 273. 15 283. 15 293. 15 303. 15 313. 15
η/cP 0. 912 0. 758 0. 652 0. 564 0. 503
T/K 323. 15 333. 15 343. 15 353. 15
η/cP 0. 442 0. 392 0. 358 0. 329