Electrostatic dust transport on the terminator of atmosphereless bodies

Journal Pre-proof Electrostatic dust transport on the terminator of atmosphereless bodies C. López-Sisterna, R.A. Gil-Hutton PII:

S0032-0633(18)30346-5

DOI:

https://doi.org/10.1016/j.pss.2019.104775

Reference:

PSS 104775

To appear in:

Planetary and Space Science

Received Date: 3 October 2018 Revised Date:

2 October 2019

Accepted Date: 8 October 2019

Please cite this article as: López-Sisterna, C., Gil-Hutton, R.A., Electrostatic dust transport on the terminator of atmosphereless bodies, Planetary and Space Science (2019), doi: https://doi.org/10.1016/ j.pss.2019.104775. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.

Electrostatic dust transport on the terminator of atmosphereless bodies C. L´opez-Sisternaa,∗, R. A. Gil-Huttona a

Grupo de Ciencias Planetarias, Departamento de Geof´ısica y Astronom´ıa, Facultad de Ciencias Exactas, F´ısicas y Naturales, Universidad Nacional de San Juan - CONICET, Av. Jos´e I. de la Roza 590 (O), J5402DCS Rivadavia, San Juan, Argentina

Abstract Small dust particles may levitate over the surface of atmosphereless bodies, but to study electrostatic dust transport during a complete rotational period it is necessary to evaluate the surface potential at the terminator zone. We simulate the photo-electron layer and the dust charging process according to previously used models for dust levitation, but we propose a modification of the models to add the effects produced by surface roughness for low solar elevation angles. The correction for surface roughness on the model showed that a positive value for the surface potential and the electric field appear at the terminator. We found that submicron particles could be in stable levitation for small gravity fields. Our results also showed that the finest regolith grains can be lost into space due to the electrostatic repulsion. Keywords: Asteroids: general, dusty plasma, levitation, photoelectron emission ∗

Corresponding author Email addresses: [email protected] (C. L´opez-Sisterna ), [email protected] (R. A. Gil-Hutton)

Preprint submitted to Planetary & Space Science

October 16, 2019

1

1. Introduction

2

The observation of the Lunar Horizon Glow by the Surveyor spacecraft

3

(Criswell, 1972, 1973; Rennilson and Criswell, 1974) and by the Apollo 17

4

mission (McCoy and Criswell, 1974; Zook and McCoy, 1991) led to the de-

5

velopment of an electrostatic dust levitation theory. During the last 40 years

6

several models arose trying to describe the physics for charging in space and

7

dusty plasma physics (Criswell, 1973; De and Criswell, 1977; Criswell and De,

8

1977; Whipple, 1981; Goertz, 1989; Nitter and Havnes, 1992; Nitter et al.,

9

1994; Colwell et al., 2005; Hughes et al., 2008), and some of these models have

10

been proposed to explain the unusual observations on asteroids (Lee, 1996;

11

Colwell et al., 2005; Miyamoto et al., 2007) and also hypothesized to occur on

12

comets (Mendis et al., 1981). In addition, different laboratory experiments

13

have confirmed dust levitation under conditions that resemble atmosphere-

14

less solar system environments (Sickafoose et al., 2002; Sheridan and Hayes,

15

2011; Wang et al., 2016).

16

The surfaces of these bodies in interplanetary space are exposed to solar

17

wind plasma and solar UV radiation; generally on the sunlit side photoelectric

18

charging exceeds plasma charging, resulting on a positive surface potential

19

(Mendis et al., 1981; Lee, 1996). These effects contribute to the generation of

20

two important currents over the surface, responsible for developing a photo-

21

electron sheath over the lit side. In general, the upper layer of the regolith

22

on a small body may be considered as an effective insulator (Sheridan et al., 2

23

1992; Lee, 1996; Kimura, 2016). Therefore, regolith dust particles will have

24

a non-zero charge while resting on the surface and, under certain conditions,

25

the electric force on sub-micrometer particles would exceed the gravitational

26

force causing dust particles to detach from the surface and levitate.

27

This electrostatic mechanism could be responsible for the redistribution

28

of regolith particles over the surface of asteroids (Veverka et al., 2001; Col-

29

well et al., 2005), but there are different arguments about how dust levitation

30

works near the terminator region because in a smooth surface the light is al-

31

most tangent to the surface. For example, Criswell and De (1977) described

32

what they called supercharging effect near the day-night boundary: the pho-

33

toelectrons recently ejected from the lit side are attracted by the positive

34

charge that has just turn into the night side of a rotating body increasing

35

the potential of the illuminated regions. Furthermore, Lee (1996) proposed

36

that the prime charging process to consider at the terminator is the photo-

37

electric effect. This author considered solar wind currents to be negligible

38

on the trailing side owing to the velocity aberration arising from the orbital

39

motion of the asteroid. More recently, Hartzell and Scheeres (2011) analyzed

40

the role of cohesive forces on sub-micrometer particles. They found that

41

taking into account cohesion, levitation may be possible only for a range of

42

particles size near the terminator of the Moon and asteroids. On the other

43

hand, Kimura et al. (2014) proposed that electrostatic forces on irregular

44

grains with rough hydroxylated surface could overcame cohesive forces near

45

the terminator. 3

46

The process responsible for detaching the particles from the surface is

47

strongly dependent on the illumination conditions. Moreover, near the ter-

48

minator the surface roughness produces areas strongly illuminated that could

49

reach high potential and should have a strong influence on the electrostatic

50

interaction of the particles with their surroundings. This effect produced

51

by roughness is not taken into account by the available models (for example,

52

Colwell et al., 2005) producing a negative surface potential near the termina-

53

tor which prevents the use of these models to simulate processes that involve

54

a complete rotation of the object.

55

In this paper we present a new way of estimating the effects of the electric

56

field close to the terminator taking into account the mean surface roughness

57

of objects with micro-gravity. We describe the electrostatic transport model

58

in section 2. In section 3 we discuss our results and in section 4 we summarize

59

the conclusions.

60

2. Electrostatic transport model

61

To simulate the photo-electron layer and the dust charging currents over

62

the surface, we initially follow the simplified monotonically-decreasing sheath

63

potential model described by Colwell et al. (2005) and Hughes et al. (2008)

64

which is briefly explained below.

65

The model assumes that the solar UV radiation strikes the surface and

66

release electrons of at least the same energy of the incoming photons, but at

67

the same time the solar wind hit the surface producing an electron current. 4

68

If the photoemission process results to be more effective than the solar wind

69

charging process, then the sunlit surface becomes positively charged. The

70

surface will continue charging until the sum of the currents becomes zero.

71

Then, the surface potential, φs , is determined by equating the photo-electron

72

(Ipe ) and the solar wind (Isw ) currents at the surface (Whipple, 1981; Colwell

73

et al., 2005):

Ipe Isw

 −qe φs cos θsun , = πrd qe Ipe0 exp kB Tpe r   kB Tsw qe φs 2 = πrd qe nsw 1+ , 2πme kB Tsw 

2

(1) (2)

74

where rd is the grain radius, qe is the absolute value of the electron charge,

75

me is the mass of the electron, kB is the Boltzmann constant, and θsun is the

76

complementary angle of the solar elevation angle. The photo-electron and

77

the solar wind temperatures are Tpe and Tsw , respectively, for which we used

78

values of 2.2 eV (Willis et al., 1973) and 10 eV, where the second value is

79

well below the energy range where secondary electron production becomes

80

important.

81

In order to calculate the photo-electron current at the surface (Ipe ), we

82

assumed that it has the same photo-emissive properties as the lunar regolith

83

(Willis et al., 1973; Sternovsky et al., 2002), but we take into account that the

84

usual value for the emitted photoelectrons proposed byWillis et al. (1973) was

85

underestimated by a factor of 2.1 (Senshu et al., 2015). Then, the parameters 5

86

used for the emitted photo-electron flux for normal incidence of light, Ipe0 ,

87

and the electron density of the solar wind, nsw , are scaled to its value at 1 au:

Ipe0 nsw

  5.88 × 109 electrons = , d2sun cm2 s   5 electrons = 2 . dsun cm−3

(3) (4)

88

Besides, the photo-electron sheath is a region of increased electron density

89

near the surface formed as a consequence of the release of photo-electrons

90

and its electric attraction to the positive surface. Then the photo-electron

91

density is defined by:

npe0 = 92

2Ipe0 cos θsun , vpe

(5)

where vpe , the characteristic photo-electron velocity, is: r vpe =

2kB Tpe ≈ 880 km/s. me

(6)

93

Then, an electric field appears as result of the potential difference between

94

the surface and this sheath. Grard and Tunaley (1971) defined the electric

95

field and the photo-electron density as function of height (z), above the

96

surface:

6

√ −1  2 2φs ∆z E (∆z) = , 1+ √ λD 2λD  −2 ∆z npe (∆z) = npe0 1 + √ , 2λD 97

(7) (8)

where: s λD =

ε0 kB Tpe , npe qe2

(9)

98

is the Debye length at the surface, which indicates the width of the photo-

99

electron sheath, and ε0 is the permittivity in vacuum.

100

2.1. Charge and dynamics of dust particles

101

Dust grains also release electrons through the photoelectric effect, and col-

102

lect solar wind electrons and photo-electrons from the photo-electron sheath

103

in a similar way as happens on the surface. This process is time dependent

104

and results in a variation of the grain charge, Qd , produced by the currents

105

balance: dQd = Ipe,d − Ie,d − Isw,d , dt

(10)

106

where Ipe,d , Ie,d and Isw,d are the currents due to photo-emission from the

107

particle, to the collection of photo-electrons emitted by the surface, and to

108

the capture of solar wind electrons, respectively. These currents depend on

7

109

the grain charge, and in the case it is charged positively:

−qe φd Ipe,d = πrd 2 qe Ipe0 exp , kB Tpe r   qe φd 8kB Tsw 2 1+ , Isw,d = πrd qe nsw πme kB Tsw r   8kB Tpe qe φ d 2 1+ , Ie,d = πrd qe npe πme kB Tpe

(11) (12) (13)

110

where φd is the electric potential of the grain. In the case of a negative

111

potential, the currents are given by:

Ipe,d = πrd 2 qe Ipe0 , r

8kB Tsw qe φ d Isw,d = πrd 2 qe nsw exp , πme kB Tsw r qe φd 8kB Tpe exp . Isw,d = πrd 2 qe npe πme kB Tpe

(14) (15) (16)

112

If the electrostatic and the gravitational forces are balanced, the dust

113

grain levitates through the photo-electron sheath, but if an unbalance be-

114

tween these two forces occurs the charged particle moves in the radial direc-

115

tion following the equation of motion: d2 r = Qd E(∆z) − gA md , dt2

116

(17)

where gA is the object gravity, md is the grain mass, and E(∆z) is defined 8

117

by the equation 7.

118

2.2. Illumination excess due to roughness

119

If we assume in this model that the surface of the object is smooth, then

120

close to the terminator the photo-electron density and the photo-electron

121

current fall very fast and the surface potential reaches negative values for

122

θsun = 90 ◦ . However, the surfaces of solar system objects are highly irregular

123

showing macroscopic and microscopic roughness. This roughness could be

124

important in the regions near the terminator because it produces small areas

125

with orientations that are not normal to the radial direction, and then they

126

could appear illuminated by the Sun (Criswell, 1972, 1973). These small

127

regions undergo the usual process of gain and loss of electrons as the object

128

rotates, but in this case the illuminated regions constantly lose electrons

129

because they are more likely to be collected by large dark areas when they

130

fall again to the surface. As a consequence of this particular effect, the electric

131

field on the surface would increase rather than decline in the terminator zone

132

producing a greater radial acceleration than that expected from a smooth

133

surface (Eq. 17).

134

Since the effects of a rough surface near the terminator are the result

135

of the existence there of small illuminated areas which also contribute to

136

produce the total brightness of the object, we decide to estimate the value

137

of the electric field near the terminator using a formulation similar to that

138

given by Lumme and Bowell (1981a,b) to calculate the phase function for

9

139

atmosphereless bodies. According to these authors, the normalized phase

140

function for atmosphereless bodies is given by:

Φ(α) = (1 − G)Φ1 (α) + GΦM (α),

(18)

141

where α is the phase angle, G is a parameter which measures the ratio be-

142

tween the brightness produced by multiple scattering and the total bright-

143

ness, Φ1 is the phase function for singly scattered light due to a single parti-

144

cle, shadowing and roughness, and ΦM is the phase function due to multiple

145

scattering between particles. The functions Φ(α), Φ1 (α) and ΦM (α) are nor-

146

malized to their values at α = 0 ◦ .

147

148

Following the formulation originally proposed by Lumme and Bowell (1981a), we have:

Φ1 (α) = ΦS (α, D)ΦR (α, ρ)ΦP (α, σ),

(19)

149

where φS , φR , and φP are the normalized phase functions due to shadowing,

150

roughness, and single particle scattering, respectively. These functions de-

151

pend on the volume fraction D (or the porosity, 1 − D), the relation between

152

the depth and the radius of a typical irregularity on the surface (the rough-

153

ness, ρ), and the ratio between backscattering and forward scattering (the

154

asymmetry factor, σ). On the other hand, ΦM is not difficult to calculate

155

because it is similar to the phase function of a Lambert reflector:

10

φM ≈

1 [sin(α) + (π − α)(cos(α)], π

0 6 α 6 π.

(20)

156

This formulation can be used to derive a factor that allow us to estimate

157

the surface brightness, which is proportional to the illumination received at

158

different illumination angles. Although in the original formulation by Lumme

159

and Bowell (1981a,b) the G parameter depends on the wavelength used to

160

measure it, in our model it is used as a measure of surface roughness. Thus,

161

if G and the phase functions for a particular object are known and we assume

162

that α ≡ 180 ◦ − 2θsun , then the function:

ψ(θsun ) = Φ(α) − GΦM (α),

(21)

163

is the measurement of the relative contribution of the brightness (or the

164

illumination at constant albedo) due to shadowing and roughness. Then, the

165

photo-electron current and the photo-electron density modified to take into

166

account this effect are:

Ipe,r npe0,r

 −qe φs = πrd qe Ipe0 exp [cos θsun (1 − ζ) + ζψ], kB Tpe 2Ipe0 [sin θsun (1 − ζ) + ζψ] = , vpe 2



(22) (23) (24)

167

where:

11

ζ=

  2    (θ0 −θsun ) , for θsun > θ0 ; θ0   0,

168

(25)

otherwise;

and θ0 is defined as ψ(θ0 ) = 0.

169

The surface electric potential as function of the solar angle for a smooth

170

and rough surface are shown in fig. 1. These curves have a similar behavior

171

up to solar angles of ∼ 70◦ , but beyond this point the surface potential for

172

a smooth surface decrease to approximately φs ∼ −1.0 V at the terminator

173

while for an irregular surface it reaches a minimum at θsun = 85◦ and increase

174

again to reach at the terminator a surface potential of φs ∼ 2.0 V ( E(z =

175

0) ∼ 1 V /m). 6 Rough surface Smooth surface

Electric surface potential [V]

5

4

3

cc 2

1

0

-1 0

10

20

30

40

50

60

70

80

90

Solar incidence angle [Deg]

Figure 1: Variation of the surface electric potential with respect to solar-zenith angle at the equator of an spherical body.

12

176

3. Numerical results

177

To test the changes in the model to calculate the electrostatic dust trans-

178

port near the terminator, we made a computational code that simulates a

179

rotating spherical object with an arbitrary orientation of its axis of rotation.

180

The code allows to follow the particle trajectories integrating the equations

181

10 and 17 by Euler method. The parameters used to run the simulation are

182

listed in table 1. The value assumed for the porosity is usual for an aster-

183

oid and higher values (0.4 − 0.5) are found on few asteroids, like (25143)

184

Itokawa or (253) Mathilde. The roughness of 0.2 is in agreement with values

185

measured for some asteroids (Melosh, 1989; Veverka et al., 1999, 2000) and

186

the Moon (Pike, 1974). Since the parameter G changes from one asteroid to

187

another, we decided to use as an example the value of the magnitude system

188

(V-band) for (433) Eros.

189

As mentioned earlier, the motion of a dust particle due to levitation

190

will be affected by the gravity force, therefore we take three values for the

191

acceleration to study different scenarios: the first one corresponds to an

192

asteroid radius of less than a kilometer (e.g. (101955) Bennu, Nolan et al.,

193

2013), the second represents asteroids with radii of the order of 10 km (like

194

Eros, Yeomans et al., 2000), and the last value for gravity corresponds to

195

larger asteroids with radii of several kilometers (Kuzmanoski and Kovaˇcevi´c,

196

2002).

197

We run the simulation assuming that the object is at 1.8 au from the

198

Sun (neither too close where small particles would be lost into space nor far 13

199

away where they could not levitate), with a rotational period of 5 h, and two

200

orientations of the spin axis, one perpendicular to the orbital plane and the

201

other pole-on. Table 1: Initial parameters

Parameter distance to Sun, dsun asteroid gravity, gA rotational period, Ω G porosity, (1-D) surface roughness, ρ asymmetry factor, σ

Value 1.8 au 0.5 × 10−4 ; 0.5 × 10−2 ; 0.5 m/s2 5h 0.46 0.3 0.2 0

202

If we take a snapshot of the simulation, we will see the dependence of the

203

surface electric potential with respect to θsun (fig. 2). For the three profiles

204

(60◦ , 30◦ , and 0◦ in latitude and simetrical with respect to the equator) shown

205

in fig. 2, the potential is positive on the day side and at longitudes ±90◦ it is

206

possible to see the change in surface potential due to the model modification.

207

On the dark side, the region with longitudes between 90◦ and 270◦ from the

208

sub-solar point, the electric potential and the electric field were set equal to

209

zero. We also see how the maximum value for the surface potential change

210

for the different latitudes. Being lower at a latitude of 60◦ (top panel),

211

approximately 5.5 V at 30◦ (middle panel), and reaching a maximum value

212

of 6 V at the equator (bottom panel).

213

The charging mechanism of dust particles depends on the radius and

214

density of the grain, the surface properties, and the time-dependent solar

14

Latitude of 60° 6 5 4 3 2 1 0

Surface potential [V]

0

50

100

150

200

250

300

350

Latitude of 30° 6 5 4 3 2 1 0

cc

0

50

100

150

200

250

300

350

300

350

At the equator 6 5 4 3 2 1 0 0

50

100

150

200

250

Longitude [°] Figure 2: Profiles of the surface electric potential as function of longitude, for a spherical object with perpendicular spin axis to the orbital plane. In the top panel is shown the profile at a latitude of 60◦ , in the middle panel at 30◦ latitude, and in the bottom panel at 0◦ latitude. The sub-solar point is at zero degrees of latitude and zero degrees of longitude.

215

zenith angle at the location of the particle. In our simulations we use particles

216

initially deposited at the surface with electric charge and potential equal to

217

zero, radius between 0.1 and 1.1 µm, and density of 3.7 g/cm3 .

218

The most likely mechanism to give particles their initial velocities is by

219

micro-meteoroid bombardment which could break-up rocks and/or bedrock

220

into small pieces (Gr¨ un et al., 2011) and could also throw out small particles

221

by collisions. Due to this process some of the ejecta may escape the gravity

222

force of the asteroid but other particles may fall back onto the surface, so 15

223

small dust grains are formed continuously on the surface of atmosphereless

224

bodies and the micro-meteoroid bombardment provide them an initial veloc-

225

ity. In general, the escape velocity for an object with microgravity is of the

226

order of a few meters per second (Veverka et al., 2000; Fujiwara et al., 2006).

227

Extrapolating the results obtained experimentally by Wang et al. (2016) on

228

the maximum lofting height as function of the vertical initial speed, we found

229

for particles in asteroid surfaces a mean initial radial velocity of 0.4 m/s.

230

The dust grains were launched from the surface with random directions.

231

Once a grain lifts off the surface, the particle motion can be described as

232

either ballistic, escaping, or levitating. In the first case the trajectory of the

233

particle is governed by the gravity force and return to the surface in a short

234

time, being negligible the electrostatic interaction. In the second case, the

235

particle gains enough kinetic energy to escape into space. Essentially, all

236

grains launched with enough initial velocity cannot be slowed down regard-

237

less of its size. Finally, the condition for particles to levitate is when the

238

electrostatic and gravity forces are almost equal, opposite in direction and

239

the electrostatic force varies slightly in time.

240

We first simulate an object with a gravity acceleration of 0.005 m/s−2

241

and a five-hour rotational period. We found that the crossing time of the

242

photo-electron sheath for all particles with radii below 0.3 µm is very short

243

and they cannot accumulate enough charge to reverse their motion, resulting

244

in an escaping trajectory. By contrast, particles with radii between ∼ 0.3 µm

245

and 0.5 µm acquired enough charge to interact with the photoelectron sheath 16

246

until they are no longer on the lit side of the object. When these particles

247

approach the region near the terminator, the photoelectron density decreases

248

and the particles fall back onto the surface. At the day-night boundary dust

249

grains of this size are strongly repelled by the positively charged surface

250

(fig. 1), and as a result, the particles escape into interplanetary space (fig. 3). 850

0.3 µm 0.5 µm 0.7 µm 0.9 µm 1.1 µm

800 750 700 650

Height [meters]

600 550 500 450

cc

400 350 300 250 200 150 100 50 0 0

5000

10000

15000

20000

25000

30000

35000

Time [seconds]

Figure 3: Evolution of particles in time, for a rotating object with a size comparable to Eros and its spin axis perpendicular to the orbital plane. All particles are launch with an initial radial velocity of 0.4 m/s.

251

For larger particles (fig. 3) we find different scenarios according to their

252

size, their initial location, and their initial velocity vector. For example, we

253

found that for some particles with size between 0.7 − 0.9 µm the electric

254

force is almost balanced by the force of gravity allowing these particles to

255

go through the sheath and at the terminator they could fall to the surface

256

and remain at rest during the night. Others levitate while they are being

257

illuminated and at the terminator region, where the sheath has fewer pho-

17

258

toelectrons, the gravity force pull these particles down and as soon as they

259

reach the surface they are electrostatically repelled.The particles with radii

260

of 1.1 µm usually follow ballistic trajectories; but when these particles re-

261

main under sunlit areas they constantly lose electrons and this allows them

262

to levitate for longer periods (fig. 3).

263

If the initial velocity of the grains are set to zero we found that particles

264

with radii smaller than 0.3 µm are lost before they cross the terminator.

265

Then, it seems that in asteroids with radius similar to Eros the smallest

266

particles can be lost regardless of the initial velocity. On the other hand,

267

particles larger than 0.5 µm that were initially at rest get charge and levitate

268

while the solar phase angle is less than ∼ 90◦ . Then, on the night side the

269

grains fall back to the surface until they are on the day side again (fig. 4). 400

rd= 0.5 µm, Vi= 0 m/s rd= 0.5 µm, Vi= 0.4 m/s rd= 0.7 µm, Vi= 0 m/s rd= 0.7 µm, Vi= 0.4 m/s

350

Height [meters]

300

250

cc

200

150

100

50

0 0

5000

10000

15000

20000

25000

30000

35000

Time [seconds]

Figure 4: Height as function of time for two set of particles, with zero and non-zero initial radial velocity, on an Eros-like object with a perpendicular spin axis.

270

We also simulate particles under gravity accelerations of 0.5 × 10−4 and 18

271

0.5 m/s2 obtaining completely opposite results: in the first case all particles

272

smaller than 1.1 µm would be lost, while in the second case the dynamics of

273

the particles are governed by gravity and none of them can levitate.

274

In the case of a face-on object, i.e. a whole hemisphere been illuminated

275

permanently, we found that even the largest particles could escape the as-

276

teroid gravity if they receive an impulse in the zone close to the terminator.

277

The particles launch from the day side levitate while they are illuminated

278

(fig. 5), they get charged and are attracted by the photoelectron sheath while

279

those that reach the dark side hit the surface and stay there. 1000

0.5 µm 0.7 µm 0.9 µm 1.1 µm

950 900 850 800 750

Height [meters]

700 650 600 550

cc

500 450 400 350 300 250 200 150 100 50 0 0

5000

10000

15000

20000

25000

30000

35000

Time [seconds]

Figure 5: Height as a function of time for particles on an object surface, with a face-on configuration. All particles are launch with an initial radial velocity of 0.4 m/s.

280

4. Conclusions

281

Some previous works (De and Criswell, 1977; Criswell and De, 1977; Lee,

282

1996) suggested that the electric field at the terminator might be of several 19

283

kV m−1 due to the potential difference between the day and night sides.

284

Although on the model of De and Criswell (1977) and Criswell and De (1977),

285

a sharp boundary at the terminator is being assumed, this could mean that

286

the electric field would not be as intense in the day-night boundary as they

287

found.Mendis et al. (1981) argued that the potential is positive around the

288

sub-solar point and then it decreases to negative values near the terminator.

289

We found that the electric potential and the electric field decrease from the

290

sub-solar point up to a minimum (∼ θsun = 85◦ ,see fig. 5), and then at

291

the terminator the electric potential rise to a positive value. The change

292

in the behavior of the electric potential found in this work is the result of

293

the surface roughness contribution to the electric field and to the potential

294

at the terminator. The G and Φ1 are the only parameters, used in our

295

model, that depend on the rugosity of the surface and on the particular

296

properties of the surface of the objects. Only in the case of a rarely large

297

value of G (smooth surface) the model will show a negative surface potential

298

in the terminator zone. Taking into account the roughness contribution, we

299

can study and simulate the evolution of regolith particles during a complete

300

rotational period and evaluate which are the surface regions where the dust

301

grains could accumulate.

302

The results of the simulations made considering the roughness contri-

303

bution at the terminator agree with Lee (1996), Colwell et al. (2005) and

304

Miyamoto et al. (2007) in their conclusion that electrostatic dust transport

305

might be happening on some asteroids, although we are aware that the photo20

306

electron sheath structure depends on the plasma and surface properties (Nit-

307

ter et al., 1998; Poppe and Hor´anyi, 2010). Then our results support the

308

idea that on some small asteroids the finest regolith particles which receive

309

an initial velocity may escape due to the electrostatic force acting on them

310

(Yamamoto and Nakamura, 2000). We also find that on illuminated areas of

311

an asteroid a submicron dust grain would be on stable levitation (Lee, 1996;

312

Colwell et al., 2005). Moreover, particles with radii between 0.5 and 0.7 µm

313

might levitate, without any external impulse, after traveling from the dark

314

to the illuminated side of an asteroid and finding a positive surface potential

315

at the terminator.

316

It will be subject of future studies the correlation between our model

317

with data collected by rendezvous missions, like Hayabusha 2 (Ogawa et al.,

318

2019; Tachibana, 2019) and OSIRIS-REx (Lauretta et al., 2019). However,

319

L´opez-Sisterna et al. (2019) report polarimetric observations that could be

320

an observational evidence about the presence of an electrostatic levitation

321

mechanism on the surface of some asteroids.

322

acknowledgements

323

The authors thank Prof. Julio Fern´andez and an anonymous referee for

324

their review which led to an improvement of the paper, and gratefully ac-

325

knowledge financial support by CONICET through PIP 112-201501-00525

326

and San Juan National University by a CICITCA grant for the period 2018-

327

2019. 21

328

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• • •

Sub-micron particles may transport by electrostatic levitation over asteroid surfaces. Contribution of the surface roughness to the the illumination conditions near the terminator zone of an asteroid. Computational model for the photoelectron layer and the dust charging process.

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.