476 10 Transport Processes
Metal plate
of area
Electrical
power
supply
Metal plate
of area
d
Figure 10.9 An Electrically Conducting System (Schematic).
The conductivity has the units ohm−^1 m−^1. The ohm−^1 has been called themho(ohm
spelled backwards) but the SI name for ohm−^1 is thesiemens, denoted by S, so that
the conductivity has the units Siemens per meter (S m−^1 ).
We define thecurrent densityjas a vector with magnitude equal to the current per
unit area and with the same direction as the current:
j|j|
I
A
(10.5-4)
whereAis the cross-sectional area of the conductor andIis the current. Ohm’s law
can be written
j
I
A
V
RA
EEEd
rd
EEE
r
σEEE (10.5-5)
whereEEE is the magnitude of the electric field, equal toV/dfor an object like that of
Figure 10.9.
Consider a solution of an electrolyte solute with one cation and one anion. Let the
mean velocity of cations be denoted byv+and the mean velocity of anions be denoted
byv−. At equilibrium these mean velocities vanish because as many ions will be
moving in a given direction as in the opposite direction. In the presence of an electric
fieldv+andv−will be nonzero, in which case they are calleddrift velocities. The
current density is the sum of a cation contribution and an anion contribution. On the
average cations no farther from a fixed plane than a distance equal tov+times 1 second
will pass in 1 second. For unit area, the number of cations passing the fixed plane per
second is
number of cations per unit area per secondc+NAvv+ (10.5-6)
wherec+is the concentration of the cations in mol m−^3 andNAvis Avogadro’s constant.
The charge passing per second due to the cations is
charge per unit area per second due to cationsz+ec+NAvv+ (10.5-7)
whereeis the charge on a proton, 1. 6022 × 10 −^19 C, andz+is the valence of the
cation (the number of proton charges on one ion). A similar expression can be written