The effect of an external electric field on the scavenging of aerosol particles by cloud drops and small rain drops

The Effect of an External Electric Field on the Scavenging of Aerosol Particles by Cloud Drops and Small Rain Drops P. K. WANG AND H. R. P R U P P A C H E R Department o f Atmospheric Sciences, University o f California, Los Angeles, California 90024 Received July 2, 1979; accepted S e p t e m b e r 17, 1979 A theoretical model is described which determines the efficiency E with which aerosol particles of radius r ~< 0.5/zm are collected by water drops of radius a due to the combined action of convective Brownian diffusion, thermo- and diffusiophoresis, and electric forces c a u s e d by the presence of an external electric field and electric charges on drops and aerosol particles, but in the a b s e n c e of inertial impaction effects. T h e results of this model are combined with the results of o u r earlier model which determines the collection efficiency of drops for particles o f r > 0.5/zm due to the combined action of inertial impaction, thermo- and diffusiophoresis, and electric forces due to the presence of an external electric field and electric charges on drops and aerosol particles, but in the absence of convective Brownian diffusion. Both models combined are able to quantitatively predict E vs r for 0.001 ~< r ~< 10/zm and 8.6 <~ a ~< 438/zm, for relative humidities in the ambient air up to 100%, and for external electric fields and electric charges on drops and aerosol particles of a magnitude up to those found in thunderstorms. O u r results show that external electric fields act to significantly e n h a n c e the efficiency with which drops collide with aerosol particles of radii 0.01 ~< r ~< 1.0/~m, the size range in which E experiences a minimum. External electric fields have negligible effects on the scavenging of aerosol particles of r < 0.01 /zm and of r > 1.0/zm. 1. I N T R O D U C T I O N

It is well known that a considerable fraction of the aerosol particles suspended in the atmosphere is removed from the atmosphere and returned to the earth's surface by mechanisms which involve clouds and precipitation. Substantial contributions to the theoretical description of this scavenging mechanism have been made by (1-13). A critical review of these studies has recently been given by (14). This review showed that in previous theoretical studies electric effects on the mechanisms of aerosol particle scavenging by water drops in air were disregarded. This deficiency was partially eliminated in (14) which was a study of the effects of electric charges on the efficiency with which aerosol particles are captured by drops. For this study two theoretical models were developed which, in addition to the effects of electric charges,

considered the effects of phoretic forces, hydrodynamic forces and gravity, and convective Brownian diffusion. The present article considers the effects of an external electric field. For studying these effects the two theoretical models, developed by us earlier, were used. In model I, developed in (5-7, 12, 13) the efficiency was theoretically computed with which an aerosol particle of radius r ~> 0.5 /zm collided with a water drop in air due to the combined, simultaneous action of inertial impaction (due to hydrodynamic forces and gravity), thermo- and diffusophoresis, and electric forces. With this model, the collision efficiency was deduced from a determination of the trajectory of an aerosol particle falling at its terminal velocity around the water drop. The electric effects considered were those due to the presence of electric charges on drops and aerosol particles and those due to the presence of an 286

0021-9797/80/050286-12502.00/0 Copyright © 1980by AcademicPress, Inc. All rights of reproduction in any form reserved.

Journal of Colloidand InterfaceScience, Vol. 75, No. 1, May 1980

SCAVENGING

external electric field. The trajectory of the aerosol particle was determined from the relation dv m--=mg* dt

67rr~ (1 + OtNkn)

( v - u)

+ F T h + FDf + F e.

[1]

In this equation m, r, and v are the mass, radius, and velocity of the aerosol particle, respectively, t is time, g* = g (pp - pa)/

OF AEROSOL

PP, PP is the bulk density of the aerosol particle, pa and "0a are the density and viscosity of the air, respectively, 1 + a Nk. is the Stokes-Cunningham correction to the drag on a particle with size of the order of the mean free path length ha of the air molecules, Nkn = hair is the Knudsen number, a = 1.26 + 0.40 exp(--1.10Nkn -1) from (15), u is the velocity of the air around the falling drop, FTh is the force due to thermophoresis, FDf is the force due to diffusiophoresis, and Fe is the electric force. According to (15)

12~rr~a(ka + 2.5kpNkn)kaVT FTh =

--

287

5(1 + 3Nkn)(kp + 2ka + 5kpNkn)p

[2]

and FDf =

-67r~ar

0.74DvaMaVPv

(1 + aNkn)MwPa

,

[3]

where k a and ke are the thermal conductivities of air and the aerosol particles, respectively, Dva is the diffusivity of water vapor in air, Ma and Mw are the molecular weights of air and water, respectively, Pv is the density of water vapor in air, T is the absolute temperature, and p is the air pressure. For determining the forces due to thermo- and diffusiophoresis, vapor density and temperature fields were used which were derived by us following the method of (16) to numerically solve the convective diffusion equation. The velocity u of the air around the drop was determined from the flow fields derived by us and in (17) for the flow of air around a circulating water drop. The electric force due to net charges and image charges on drops and aerosol particles was computed using the results of(18). From a knowledge of the particle's trajectory around the drop, the collision efficiency E -

7r(a + r) 2

[41

was deduced, where Yc is the largest initial horizontal offset a particle can have and still collide with the drop (yc being measured

from the drop's axis aligned along g and sufficiently far upstream from the drop). The collision kernel was computed from K = ETr(a + r)2(V~oa - V®,r),

[5]

where V=,a and V=,r are the terminal fall velocity of the drop and aerosol particle, respectively. The present paper introduces a second model which is complementary to model I, but applies to particles of r ~ < 0.5/zm. This model (called model II) is conceptually analogous to the model II developed in (14) for studying the effects of electric charges on the collision efficiency. However, the present model II includes the effects of an external electric field in addition to the effects of electric charges, phoresis, and convective Brownian diffusion. In this paper we shall: (1) quantitatively describe the present model II, (2) give some results derived from this model, and (3) combine the results from this model with the results of model I. In our discussion, particular emphasis shall be given to the scavenging of aerosol particles in the size range within which the efficiency is minimum, a size range which we have previously termed the "Greenfield Gap" (since Greenfield, 1957, appears to have been the first to point out Journal o f Colloid and Interface Science, Vol. 75, No. 1, May 1980

288

WANG AND PRUPPACHER

the meteorological significance of this minimum in scavenging efficiency). Both models I and II predict collision efficiency and collision kernels. However, it is reasonable to assume that the efficiency with which an aerosol particle is retained by a drop after it has collided with it is unity. Under these conditions our collision efficiencies represent collection efficiencies, and our collision kernels represent collection kernels. 2. PHYSICS AND MATHEMATICS OF MODEL II

In the present model II, the collision efficiency is found from a determination of the flux of aerosol particles to a collector drop which falls at terminal velocity in air. In this model it is assumed that the aerosol particles are sufficiently small that their inertia may be disregarded. The total particle current density jp is written as j v - - - - n v v - Dp~7n, where Yp =BvFext, n is the number concentration of aerosol particles, Vp is their drift velocity, Dp is their diffusivity, Bp = (1 + ~V.Nkn)/67r~ar is t h e i r mobility, and Fext is the vector sum of the external force acting on the particle. For the case of an aerosol particle moving toward a drop as a result of Brownian diffusion, thermophoresis, diffusiophoresis, and electric and gravitational forces

[6]

where Feq is the force due to chargecharge interaction, and FeE is the force due to charge-electric field interaction. Assuming steady-state, constant diffusivity and assuming that the aerosol particles are small such that the term rag* may be neglected in comparison to FTh, FDf, and Fe, the condition of particle continuity V.jp = 0 for steady state leads to Bp(FTh + FDf -{- Feq + FeE)

× Vn - DpV2n -- 0.

BvFext" Vn - DvV2n = O,

[8]

where

jp : n B p ( m g * + FTh + FDf + Feq + FeE)

- DpVn,

In obtaining Eq. [7] we have assumed that V'(FTh + FDf + Feq + FeE) = 0. It is obvious that this is true for V'Feq since we can assume that the electric field around an electric charge on a spherical drop or aerosol particle is spherically symmetric. Therefore we may write Feq = (Ceq/R2)OR, where Ceq = QaQr, where Qa and Qr are the electric charges on the drop and aerosol particle, respectively, and where 0a is the unit vector in radial direction. For a stationary drop V.FTh -- 0 and V'FDf : 0 since then the temperature and vapor density fields are spherically symmetric around the drop. However, for a moving drop for which the temperature and vapor density fields vary with angle around the drop these conditions do not hold. We therefore follow the arguments of (14) and assume that it is reasonable to set V "(fhFxh + ?vFDf = 0, wherefh andfv are the mean ventilation coefficients for heat and water vapor transport in air (see (15)). Then fhFTh = ( C h / R 2 ) e R and fvFof = ( C v / R 2 ) ~ R . For the force due to the interaction of the charge Qr on the aerosol particle with an external electric field of strength E0 we may write FeE = EQr. Therefore V'FeE = V'(EQr) = QrV'E = 0, from Maxwell's equation. With these, we may write Eq. [7] now as

[7]

Journal of Colloidand Interface Science, Vol.75, No. 1, May 1980

Fext = (CTh + CDf -[- Ceq) ~

1

dR "[- QrE.

[9]

Great difficulties are encountered if one wants to exactly solve Eq. [8] together with Eq. [9]. Therefore, we pursue the superposition method which, although less accurate, leads to a useful solution. For implementing this method we add the flux J1, due to phoretic effects, convective Brownian diffusion, and electric charge on drops and aerosol particles, to the flux J2, exclusively due to the drift of electric charges in an external electric field. (Ac-

SCAVENGING OF AEROSOL ............ +

F ........... I

fir

+

=0

--

t I I _a_

(o)

289

f~'/2noBpQrEo 30=0

4-

× [(1 + 2aar3) COS01 (b)

FIG. 1. Arrangements of electric charges and electric fieldsfor whichthe presentcalculationswerecarded out. cording to (19), the method of superimposing fluxes has been proven useful in predicting realistic values for the charging rate of water drops of ions.) A solution to Eq. [8] together with Eq. [9] without the electric field term has been obtained in (14). Under these latter conditions the flux of particles to the drop is

X r 2 sin0d0d~.

The first integral pertains to the drop hemisphere attractive to aerosol particles, while the second integral pertains to the drop hemisphere repulsive to aerosol particles. Thus, no particles are captured on this latter hemisphere. We therefore set the second integral to zero, and integrate only over the first integral, to get

J2 =

noBpQrEo3 =0

J1 = I DPfp(Vn'dS)

~r12

× c o s 0 a 2 sin0d0d~

[10]

= 37rnoBvEoQ~a 2. 47rnoBpC [' BpC ~ exp ~ - 1 IDpfpa )

[11]

( 2°3t

Er = E0 1 + r3 ] COS0"~R

[12]

E0 = --Eo (1 - 2a3) r 3 sinO'ko,

[13]

wherein we have neglected the forces due to image charges. The total flux can be computed by evaluating the integral

J = i~ noBvQr(E'dS)

=0

foT

[14]

noBpQrEo [ ( 21 a+3 )

=~r/2

× r 2 sinO dOd~

[16] [17]

Flux addition yields

J = Ji + J2 = 37moBvEoQra z

where no is the number density of aerosol particles at R = ~. The flux J2 due to the drift of electrically charged aerosol particles toward a conducting sphere in an external electric field can be found by considering that the flux density due to this drift is noBpQrE, where E has the components

= fi~

[15]

cos0 ] F3

4rmoBvC

+

[18] exp(BvC/Dvfva)- 1 Equation [17] is identical to the equation describing the transport of ions toward a conducting sphere in a uniform external electric field due to pure condition, except that the ion mobility is now replaced by the mobility of the aerosol particles (19). From Eq. [18] we find for the collection kernel J K - 37rBpEoQra 2 no

+

4~BpC exp(BpC/Dpfpa)-

1

[19]

taking into account capture of aerosol particles due to Brownian diffusion, due to phoretic forces, and due to electric forces caused by electric charges on drop and aerosol particle and by the presence of an external electric field. Since the collision efficiency is related to the collision kernel by

E = K/rc(a + r)2(V~,a - V~,r)

[20]

Journal o f Colloid and lnterJace Science, Vol. 75, No. 1, May 1980

290

WANG AND PRUPPACHER

we find E -3BvE°Qra2

+ 4BpC/[exp(BpC/Dpfva) -

1]

[21]

(a + r)2(V=.a - Vo%r)

In using Eqs. [19] and [21] consideration has to be given to the fact that an electrically charged drop will accelerate (or decelerate) in an external electric field, thus altering its terminal velocity V=., and with it, the ventilation coefficients fv, fh, and fp. The terminal velocity of a charged drop in the presence of an external electric field may be c o m p u t e d from formulae given in (20) and the relation 6"rr'Oaa V ~ ' a \

<- E0 -< 3000 V/cm, typical for atmospheric clouds developing into thunderstorms. The two electrical configurations for which our computations were carried out are summarized in Fig. 1. In the present computation we also assumed that fh "~fv, where fv is the ventilation coefficient for water v a p o r in air given in (22). F o r evaluating fp we assumed that its functional dependence

CDNRe t 24 ]

i0 z 0 = 8.6ffrn

47]"

- --

3

a3g(Pw - Pa) + Qa + Eo,

[22]

where c D is the drag force coefficient, and NRe = 2aV=,aPa/rla. 3. R E S U L T S A N D D I S C U S S I O N

In the present study Eq. [21] was evaluated for 0.001 _< r -< 0.5 /zm and for 8.6 --- a - 438 ~m. The air in the environment of the falling drop was assumed to have relative humidities of 50, 75, 95, and 100%. The thermal conductivity of the aerosol particle was assumed to be kp = 0.001 cal cm -a sec -1 °K-1 (=4.19 x 10-1 J m -1 sec -1 °K-l). The values used for ka, ha, ~a, and Dva were those given as a function of t e m p e r a t u r e and pressure in (15). All computations were carried out for 900 m b a r and 10°C. The drops and aerosol particles were assumed to be either uncharged or to carry an electric charge of magnitude Qa = qa a2, Qr = qr r2, where qa = 0, 0.2, or 2.0 esu cm -2, qr = 0, 0.2, or 2.0 esu cm -2, where a and r are in centimeters, and where Qa and Qr are in electrostatic units. This drop size dependence of the electric charges is that proposed in (21) for the mean thunderstorm charge on drops (see Appendix). The external electric fields were assumed to have field strengths of 50 Journal of Colloid and Interface Science, Vol. 75, No. 1, May 1980

iOt >Z W

~5

~ i0 ° u_ !3_ w

~ e

7

z

_o t0-J _J _1 0 tj

iO-2

1

0

0.001

-

0.01

PARTICLE

3

~

0.1

RADIUS

1.0 (#.m)

FIG. 2. Effect of particle size, electric charge, and external electric field on the efficiency with which aerosol particles of various radii collide with a water drop of radius a = 8.6 /xm in air of 900 m b a r and 10°C. Solid lines represent results derived fi'om model II. Dashed lines represent results derived from model I. R H is relative humidity of the air; qa = Qa/a2, qr = Q~/rZ; curves (1) to (4) are for [qa[ = ]qrJ = 0, E0 = 0, and R H = 50, 75, 95, and 100%, respectively; curves (5) to (7) are for Iqal = ]q,I = 2 esu c m -2, E0 = 0, and for 50, 75, and 95%, respectively; curves

(8)to(It)are for Iqol = [qr] = 2esacm-2, E0 = 3000 V/cm, and for RH = 50, 75, 95, and 100%,respectively.

SCAVENGING OF AEROSOL

10z

i0 i I

0=18.6~m

~ io° _ ,7

? mo _o2 _J 0

LO -2

i0 "3-

i i l lllllI

0.001

I I I IIIJii

001 PARTICLE

I l~k.lltllJ

0.I 1.0 RADIUS (M.m)

291

ever, in this size range phoretic and electric forces play an important role. (2) Curves 1 to 4 in Figs. 2 to 10 demonstrate that, in absence of electric forces, phoretic forces may raise E by more than one order of magnitude as the relative humidity R H decreases from 100 to 50%. Also, with decreasing R H the minimum in E shifts to increasingly larger values of r. (3) With decreasing size of the collector drop the Greenfield Gap becomes progressively deeper and narrower, and shifts progressively toward larger values of r. This result is due to the fact that phoretic forces affect the Greenfield Gap more strongly on the small particle side than on the large particle side. We also note that the collision efficiencies in the Greenfield Gap increase rapidly with decreasing radius of the collector drop, reaching a value of E ~ 1 for drops of a = 10 /xm, if R H <~ 95%. Also, it is worth noting that the

FIG. 3. Same as Fig. 2 except for a drop radius of 18.6 /xm.

lO°F O=30/zm on the Reynolds number and Schmidt number Nsc is the same as that given in (22) for fv, except that now instead of Nsc,v = va/Dva we used Ns~,p = va/Dpa as the diffusivity of the aerosol particle in air. Values for Dp~ and justifications for both of the above assumptions are given in (15). The results derived from a combination of our computations using model I1 with our previous computations using model I (14, 23) are summarized in Figs. 2 to 15. From Figs. 2 to 10 the following conclusions may be drawn: (1) The variation of the collision efficiency E with aerosol particle radius r undergoes a minimum at 0.01 ~< r ~< 2/xm. This minimum, designated here as the "Greenfield G a p , " is a result of the fact that Brownian convective diffusion dominates particle scavenging for r < 0.01 /zm, while inertial impaction dominates particle scavenging f o r r > 1 /~m. For particles ofO.O1 ~< r ~< 1 /zm, n e i t h e r o f these two processes is very effective. How-

I0°

w

~

iO-2

5 o

I0 -3

i 0 "4]

4

I

0.001

~ fllll~l

I

0.01 PARTICLE

I Ililld

I

I JaJIJII

0.I 1.0 RADIUS (it.m)

FIG. 4. Same as Fig. 2 except for a drop radius of 30 /zm. Journal of Colloid and Interface Science, Vol. 75, No. 1, May 1980

292

WANG AND PRUPPACHER

i0°

I0 ° o=lO6/zm

10" z

iiio

r ,~\

I0-z

u. laJ

\\ \\\,

~, 10-3

3~, \x

j--

10"2

J I0-4

10.5 i ] i IIIHI 0.001 0.01 RADIUS

I I I llllll 0.I

OF AEROSOL

{ I

illllll

l!l

i Illlll

1.0

I

I0.0

I IIIIIII

0,001 RADIUS

P A R T I C L E (H.m)

FIG. 5. Same as Fig. 2 except for a drop radius of 42 /xm.

gap region is not only the result of the competitive action of Brownian diffusion and inertial impaction. Figures 5 to 10 show that inertial impaction creates its own gap

I

I lllllll

0.01 OF AEROSOL

I

I llllllt

I

I lllllll

0.I 1.0 P A R T I C L E (/J.m)

I0.0

FiG. 7. Same as Fig. 2 except for a drop radius of 106 /zm.

(see dashed curves) d u e t o the fact that

particles of sufficiently small sizes are caught in the rear of the drop, as trajectory analysis reveals (5, 6, 13).

i0 °

i0 °

Q=72F.m

0 =173/J,m

.,

i

/

I°l

/

i0 -I >-

f 8 9

z bJ

j

,?

~, iO-z w

~

I i

$

I

\\ ix

rl

\ \\

G

io"2

.

8

,:,,o

EbJ

fl

II

10-3

io-~

(/I

7

du

8

4 10- 4

~0-5|

I0"

I

0.001 RADIUS

I I IIIIII

I

I I Illlll

0.01 OF A E R O S O L

I

I I l llIIl

0.I PARTICLE

I

I I lJllld

1,0

I0.0

(/J.m)

FIG. 6. Same as Fig. 2 except for a drop radios of 72 ~ m . Journal of Colloid and Interface Science, Vol. 75, N o . 1, M a y 1980

[0 "S

I

I

0.001 RADIUS

I llllll

l

i I111111

0.01 OF AEROSOL

I

I I lllllI

0.I PARTICLE

1.0 (/J.m)

I

I I IIIIII

I0.0

FIG. 8. Same as Fig. 2 except for a drop radius of 173 /xm.

293

S C A V E N G I N G OF A E R O S O L

F a=310/zm

I0°

/

IO'Z r

a :42/.tm

// //

Id~ k

//

10-3 i m

mE

_~ iO-Z _

u v

uJ

g io-3

.J bJ Z

5,1

bJ v

03

g I0 "'~

.

10-4

~f

10- s

.J J Q

10"o IO"

I

I IIIIIII

0.0(

I

I Illllll

0.01

RADIUS

I

I I IIIII]

0. I

I

I IIIIIII

IOD

1.0

OF AEROSOL PARTICLE (Fcm)

El6. 9. Same as Fig. 2 except for a drop radius of 310 /zm.

1

0 O.OOI RADIUS

OF

O.(31

7

~

AEROSOL

O.I

1.0

PARTICLE

(/zm)

FIG. i 1. Effect of particle size, electric charge, and external electric field on the collision kernel of a water drop of radius a = 42 /zm colliding with aerosol particles in air of 900 mbar, 10°C, and R H = 100%, from model II. (1) = Iq, I = 2 esu cm -2, E0 = 3 0 0 0 V/cm; (2) Iqol = Iq, I = 2 esu cm -z, E0

i0 -I _-- 0:458/~m

Iqol

>-

= 500 y/cm; (3) Iqol = Iq, I = 0.2 esa cm-2, eo

10- 2

=3000 z LIJ

g

II

~. iG 3

5

Z

10-4

O3 .J 0 0

10-5 I

10-6/

~ ~ ,,~ltJl

O.OOI

O.OI

i ~ ~J~.l

O.I

esu cm -=, E0

e s u c m -2, E0 = 0,

where q. = Q./a 2, and qr = Q~/r 2.

LI. ~J

2

V/cm; (4) ]q.I = lqr[ = 0 . 2

= 500 V/cm; (5) [qo I = [q,I = 0

t i ill~.l

I.O

PARTICLE RADIUS (/~m) FIG. 10. Same as Fig. 2 except for a drop radius of 438 /xm.

(4) If electric charges reside on drops and aerosol particles and an external electric field is present of a magnitude which is typical in thunderstorm situations, E is raised, and this raise is greater the larger the relative humidity and smaller the collector drop. In this manner the Greenfield Gap is substantially reduced and transformed into a shallow minimum whose position is located at a considerably smaller value of r than that of uncharged drops and particles. Also, this shift is the more pronounced the smaller the size of the collector drop. We further notice that the collision efficiency enhancing effect of electric charges and fields is confined to Journal o f Colloid and Interface Science, Vo|. 75,

N o . 1, M a y 1980

294

WANG AND PRUPPACHER "3 I0.~,

0=42~m

i0-I -

(0)

(b)

a =310/zm

v

r =O.O01u.m

r :O.O01~rn z w

w

=o.,:°°'°5~

~ I0"

=0.005

~,o-3

_J

_1 0 u I0"

iO-Z

=

=O. Ip.m

,

10.4 0. I

I

J

I0

OJ

I

i

t

, I IJl,I

i

L ~

~ , ~=I

50

L

I00

i

L

I 1 , , , I

500 (voltslcm)

ELECTRIC

I

I000

i

I

,

I i ,11

i

I i i iii

50

3000

j

I0

I (esu)

(esu)

i

I

I00

I , ,,ll

500

I

IO00

I

3000

(voltslcrn]

ELECTRIC

FIELD

FIELD

FIG. 12. Variation with electric field strength of the collision kernel of a water drop of radius: (a) 4 2 / z m and (b) 310 tzm, colliding with aerosol particles in air of 900 mbar, 10°C, a n d R H = 100%, for lq, [ = Iqr ] = 2.0 esu cm-Z; f r o m m o d e l II.

with charged aerosol particles in the presence of an external electric field is actually reduced b e l o w the efficiency in the absence of an external electric field. This result is due to a substantial increase of the moving speed of the drops and aerosol particles, causing a reduction of the interaction time b e t w e e n the drops. H o w e v e r , this reduction

aerosol particles of 0.01 <- r ~< 1 /xm. For r < 0.01 /zm and r < 1 /_tm electric effects are unimportant. (5) Figures 1 to 4 display yet another interesting effect o f external electric fields. The results displayed in these figures s h o w that for collector drops with a < 40 /zm the efficiency with which charged drops collide

[0"2 ~

PRESENT

10.3 ~ .

-.~b.-GROVER {1979)

--"= I0 4 L g 10.S -

x~,

==

10.6 -

10.8

IO "9

I

O.O01

3000 v,o.

I

I

L I}lill

I

I

i

0.01 RADIUS

i IIklL

I

I

t

OF AEROSOL

i

=IILIL

0.1

1.0 PARTICLE

i

L i Jiihl

10.0

(/~m}

FIG. 13. Effect of particle size and external electric field on the collision kernel of a drop ofa = 8 . 6 / x m colliding with aerosol particles in air of 900 m b a r , 10°C, a n d RH = 100%, for [qa[ = [qr[ = 2.0 esu cm -2, where qa = Qa/az, and qr = Qr/rL Journal of Colloid and lnterJace Science, Vol. 75, No. 1, May 1980

295

S C A V E N G I N G OF A E R O S O L

i0 z i iE/3

_

--PRESENT

_

- - ~ ' - - GROVER (1979)

'o

% 10-4 J w Z tr

iO-5

hl

Z 0

id ~ _

~oO9~S~'~'

O3 I

i 0 -~

_

~.-

_

0 0

tO-8 _

[ 0 .9

I

0.001

I

i Ill~ll

I

i

i ,~l]tl

0.01 RADIUS

~

i

I tlll~l

0.I OF

AEROSOL

PARTICLE

FIG. 14. Same as Fig. 12, except for [q° I = ]qr I

in E is more than compensated by the increase in V~, thus causing the values for the collision kernel to be raised by the presence of an external electric field (see Eq. [51. Figures 11 and 12 demonstrate the effect of electric charges and electric fields on aerosol particle collection in a more explicit manner. We note that for an environmental relative humidity of 100%, E is already noticeably affected by an electric field of strength o f a few hundred volts per centimeter, and an electric charge on the drops and particles of 1/10th of a mean thunderstorm charge. Thus, we must conclude that scavenging of aerosol particles by drops is enhanced by electric effects already in the prethunderstorm phases of cloud and precipitation development. (Note in Fig. 11 that the particular order of the curves K vs E0 for various r is due to the Greenfield Gap.) We also find that the electric effect is negligible for very small particles since they carry a low charge due to this small size. While Figs. 1 to 10 apply to an electric field of strength E0 = 0 or 3000 V/cm, and to

I

1.0

t0.O

(/.zm) =

0.2 esu cm -2.

mean thunderstorm charges ]qa ] = 0 or 2.0 esu cm -z and ]qrl = 0 or 2.0 esu cm -~, Figs. 11 to 14 demonstrate how K varies with varying E0, qa, and qr- Thus, we note from Figs. 11 and 12 that for Iqol = 2, -- 2 a critical, external electric field of about 200 V cm -1 is required, whatever the aerosol particle size, to effect the efficiency with which the particle is captured by an electrically charged drop. At 500 V cm -1 the electric effect is already significant. In Figs. 13 and 14 the effect of varying electric field strengths on the position of the Greenfield Gap is demonstrated. We note from these figures that as E0 increases the Greenfield Gap shifts toward smaller values of r. In Fig. 15 the effect of Q a = 2 . 0 a s and Q~ = 2.0 r 2 on the collision kernel for E0 --~ 3000 V cm -1 is plotted. We note the shallowness of the Greenfield Gap at these large electric field strengths and the increase of the collection kernel with increasing electric charge on the drop, i.e., with increasing collector drop size. It is unfortunate that at present no experimental data are available against which our

Iqrl

Journal of Colloid and Interface Science, Vol. 75, No. 1, May 1980

296

WANG AND PRUPPACHER 10° I0

-....

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GROVER($979}

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FIG. 15. Effect of particle size and drop size (drop change) on collision kernel of drops colliding with aerosol particles in air of 1000mbar, 20°C,RH = 100%, for a = 8.6, 18.6, 30/~m; and in air of 900 mbar, 10°C, RH = 100%, fora = 42, 72, 106, 173, 310, 438 /~m; for Iq~l = ]q~l = 2.0 esu cm% and for E0 = 3000 V/cm, where q~ = Q~/a2;the solid lines represent results derived from model II; the dashed lines represent results derived from model I. p r e s e n t theoretically d e r i v e d data c o u l d be c h e c k e d quantitatively. H o w e v e r , o u r theoretical results are qualitatively consistent with the e x p e r i m e n t s o f (24) for drops 620 /xm and 1.82 m m in radius and v a l u e s o f qa b e t w e e n a b o u t 0.1 and 1.0 esu c m -2. W e also n o t e that an experimental verification o f o u r theoretically d e r i v e d results for uncharged drops and uncharged aerosol particles in the absence o f an external electric field has b e e n presented in (14). A n experimental verification o f o u r theoretically derived results for electrically charged drops and electrically charged aerosol particles in the absence o f an external electric field has been given in (24). APPENDIX O b v i o u s l y , the smallest charge an aerosol particle can c a r r y is Qr = 4.8 × 10 -l° esu, which is equal to one electron charge. Smaller particles c a r r y no charge. T h u s , it Journal of Colloid and Interface Science, Vol. 75, No. 1, May 1980

a p p e a r s that o u r f o r m u l a t i o n Qr = qrr z applies only to aerosol particles of r --< (4.8 × 10-1°/qr) 1/~, i.e., to aerosol particles o f r <~ 0.2/zm, if we a s s u m e q r = 2.0 esu c m -2. H o w e v e r , since m o d e l I c o n s i d e r e d only particles o f r > 0 . 1 / z m while m o d e l II considered particles o f 0.001 - r - 0.1 ~ m the a b o v e restrictions apply only to model II. On the o t h e r hand, m o d e l II did not c o n s i d e r the m o t i o n o f individual particles but r a t h e r the flux o f a whole assembly o f particles s o m e o f w h i c h c a r r y z e r o charge while others c a r r y 1, 2 . . . . . e l e c t r o n charges. T h e r e f o r e we a s s u m e that, in the m e a n , the electric charge o f the w h o l e a s s e m b l y o f particles affecting the s c a v e n g i n g o f the p o p u l a t i o n o f particles could be given b y Q~ = qrr 2. ACKNOWLEDGMENTS The authors acknowledge the financial support of the Atmospheric Sciences Section of the U. S. National

SCAVENGING OF AEROSOL Science Foundation under Grant ATM 75-9999, the Environmental Protection Agency under Grant R806257010, and the Lawrence Livermore Laboratory under Grant PO 7683403.

12. 13.

REFERENCES 14. 1. Greenfield, S., J. Meteorol. 14, 115 (1957). 2. Slinn, W. G., and Hales, J. M., "Precipitation Scavenging--1970," p. 411, AEC Symposium, Richland, Wash., 1970. 3. Slinn, W. G., and Hales, J. M., J. Atrnos. Sci. 28, 1465 (1971). 4. Young, K. C., J. Atmos. Sci. 31,768 (1974). 5. Beard, K. V., J. Atmos. Sci. 31, 1595 (1974). 6. Beard, K. V., and Grover, S. N., J. Atmos. Sci. 31, 543 (1974). 7. Grover, S. N., and Beard, K. V., J. Atmos. Sci. 32, 2156 (1975). 8. Pilat, M. J.,J. AirPollut. Contr. Ass. 25, 176(1975). 9. Pilat, M. J., and Prem, A., Atmos. Environ. 10, 13 (1976). 10. Pilat, M. J., and Prem, A., J. Air Pollut. Contr. Ass. 27, 982 (1977). 11. Slinn, W. G., Precipitation Scavenging (Air Resources Center, Oregon State University, RLO-2227-T27-2), in "Atmospheric Sciences

15.

16. 17. 18. 19. 20. 21. 22. 23. 24. 25.

297

and Power Production--1979" (D. Sanderson, Ed.), Chap. 11. Grover, S. N., Pure Appl. Geophys. 114, 509 (1976). Grover, S. N., Pruppacher, H. R., and Hamielec, A. E., J. Atrnos. Sci. 34, 1655 (1977). Wang, P. K,, Grover, S. N., and Pruppacher, H. R., J. Atmos. Sci. 35, 1735 (1978). Pruppacher, H. R., and Klett, J. D. (Eds.), "Microphysics of Atmospheric Clouds and Precipitation." Reidel, Dordrecht, 1978. Woo, S., and Hamielec, A. E., J. Atmos. Sci. 34, 1664 (1971). LeClair, B. P., Hamielec, A. E , and Pruppacher, H. R., J. Atmos. Sci. 29, 728 (1970). Davis, M. H.,J. Mech. Appl. Math. 17,499 (1964). Klett, J. D., J. Atmos. Sci. 28, 28 (1971). Beard, K. V., J. Atmos. Sci. 33, 851 (1976). Takahashi, T., Rev. Geophys. Space Phys. 11, 903 (1973). Beard, K. V., and Pruppacher, H. R., J. Atmos. Sci. 28, 1455 (1971). Grover, S. N., private communication (1979). Lai, K. Y., Dayan, N., and Kerker, M., J. Atrnos. Sci. 35, 674 (1978). Wang, P. K., and Pruppacher, H. R., J. Atmos. Sci. 34, 1664 (1977).

Journal of Colloid and Interface Science, Vol. 75, No. 1, May 1980