5.0
T
1
T
T
289
4.0
4
3
o
3.0
=>
"
2.0
|
3
°
3
°
LOL
0
Fig. 10—-Rate of coalescence US.
in ambient air
for saturated NaCl solution
{solution negative, water
positive).
4
+1
4
0
l
50
1
100
150
]
200
y2
!
250
300
350
5.0
TT
1
f
4.0b
4
3.0L
Ky
-
x
>
,
Fig. 11—-Rate of coalescence vs. V
4
2.0L
in ambient air for magnesium (x,
metal positive, water negative; C,
metal negative, water positive).
|
*
ro
x
x
°
f
4
Qo
x
0
0
5
T
T
T
T
T
Q
4e
o
5
_
\
I
10
20
TT
Vv
i
T
30
[
Tq
4i-
+
0
°
~
—_
oO
oO
2
”q
5b
9
oO
~_
oO
=
Soa
4
2b
=
TR
o
Qo
0
l
]
2
3
5
4
Qo
Tr
0
o
L
4
i
5
é
via
Fig. 12—Rate of coalescence vs.
V%in ambient air for copper
sheet (i) and copper-plated steel
beads (C) (solid positive, water
negative).
0
0
4
a
1
L
2
i
3
i
4
]
5
é
viz
Fig. 13—Rate of coalescence vs.
Vin ambient air for copper
sheet (C1) and copper-plated steel
beads (C) (solid negative, water
positive).