Encyclopedia of Environmental Science and Engineering, Volume I and II

(Ben Green) #1
The log-normal distribution is particularly useful for rep-
resenting aerosols because it does not allow negative particle
sizes. The log-normal distribution function is obtained by
substituting ln D p and ln  g for D p and s in Eq. (4),

.

fD

DD
p
g

p p

g

ln
ln ln

().

()











1 
2 2

2

2
π s s

exp

ln ln
(8)

The log-normal distribution has the following cumulative
distribution,

F

DD
D
g

pg
g

D
p

p


1 
2 2

2

0 2
psln s

exp

ln ln

ln

.

⎛ ()








∫ dln() (9)

The geometric mean diameter D g , and the geometric standard
deviation s g , are determined from particle count data by

ln ln

ln ln ln.

DnDN

nD DN

gipi

gipig









()

⎡⎣⎢ ()⎤⎦⎥

/

s /

2 12 (10)

Figure 1 shows the log-normal size distribution for par-
ticles having D g  1 m m and s g  2.0 on a log-probability
graph, on which a log-normal size distribution is a straight
line. The particle size at the 50 percent point of the cumu-
lative axis is the geometric mean diameter D g or number
median diameter, NMD. The geometric standard deviation
is obtained from two points as follows:

sg

p
p

p
po

DF
DF

DF
DF











at
at

at
at

84 13
50

50
15 7

.%
%

%
.%

.

The rapid graphical determination of the geometric
mean diameter D g as well as the standard deviation s g is a
major advantage of the log-normal distribution. It should
be emphasized that the size distribution on a number basis
shown by the solid line in Figure 1 differs significantly
from that on a mass basis, shown by the dashed line in the
same figure. The conversion from number median diameter
(NMD) to mass median diameter (MMD) for a log-normal
distribution is given by

ln(MMD)  ln(NMD)  3(ln s g )^2. (11)

If many particles having similar shape are measured on the
basis of one of the characteristic diameters defined in Table 1,
a variety of average particle diameters can be calculated as
shown in Table 2. The comparison among these diameters is

shown in Figure 1 for a log-normal size distribution. Each
average diameter can be easily calculated from s g and NMD
(or MMD).
Figure 2 indicates approximately the major sources of
atmospheric aerosols and their surface area distributions.
There tends to be a minimum in the size distribution of
atmospheric particles around 1 m m, separating on one hand
the coarse particles generated by storms, oceans and volca-
noes and on the other hand the fine particles generated by
fires, combustion and atmospheric chemistry. The commi-
nution processes generate particles in the range above 1 m m
and molecular processes lead to submicron particles.

PARTICLE DYNAMICS AND PROPERTIES

Typical size-dependent dynamic properties of particles sus-
pended in a gas are shown in Figure 3 together with defining
equations (Seinfeld, 1986). The solid lines are those at atmo-
spheric pressure and the one-point dashed lines are at low
pressure. The curves appearing in the figure and the related
particle properties are briefly explained below.

Motion of Large Particles

A single spherical particle of diameter D p with a velocity u in
air of density r f experiences the following drag force,

F d  C D A p ( r f u^2 /2) (12)

10 –3 10 –2 10 –1

10 –1
100

100

101

102

103

104

105

101 102 103
Dp (mm)

FOREST FIRE
PLUMES

INTENSE
SMOG
HEAVY
AUTO
TRAFFIC

VOLCANIC PLUMES

DUST STORMS

SAND
STORMS

INDUSTRY
TYPICAL URBAN
POLLUTION
SEA SALT
SOUTH ATLANTIC
BACKGROUND
NORTH ATLANTIC
BACKGROUND

CONTINENTAL
SURFACE AREA DISTRIBUTION, BACKGROUND

∆S/

∆log D

(p
mm

2 cm

-^3


)

FIGURE 2 Surface area distributions of natural and anthropo-
genic aerosols.

18 AEROSOLS


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