Horizontal and Vertical Distribution of Microplastics in Korean Coastal

Oct 8, 2018 - This is the first survey to investigate the vertical distribution and composition of microplastics >20 μm at the surface (0–0.2 m; bu...
1 downloads 0 Views 1MB Size
Subscriber access provided by Kaohsiung Medical University

Characterization of Natural and Affected Environments

Horizontal and vertical distribution of microplastics in Korean coastal waters Young Kyoung Song, Sang Hee HONG, Soeun Eo, Mi Jang, Gi Myung Han, Atsuhiko Isobe, and Won Joon Shim Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b04032 • Publication Date (Web): 08 Oct 2018 Downloaded from http://pubs.acs.org on October 8, 2018

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 26

Environmental Science & Technology

1

Horizontal and vertical distribution of microplastics in Korean coastal

2

waters

3 4

Young Kyoung Song1,2, Sang Hee Hong1,2, Soeun Eo1,2, Mi Jang1,2, Gi Myung Han1,

5

Atsuhiko Isobe3, Won Joon Shim1,2*

6 7

1

Korea Institute of Ocean Science and Technology, Geoje-shi 53201, South Korea

8

2

Korea University of Science and Technology, Daejeon 34113, South Korea

9

3

Research Institute for Applied Mechanics, Kyushu University, 6-1 Kasuga-Koen, Kasuga

10

816-8580, Japan

11 12

*To whom correspondence should be addressed

13 14

Manuscript for “Environmental Science and Technology”

15 16

Mailing Address:

17

Won Joon Shim, Ph. D

18

Oil and POPs Research Group

19

Korea Institute of Ocean Science and Technology

20

Tel: +82-55-639-8671

21

Fax: +82-639-8689

22

E-mail: [email protected]

23 24 25 26 27 28 29 30 31 32 1

ACS Paragon Plus Environment

Environmental Science & Technology

33

ABSTRACT:

34

This is the first survey to investigate the vertical distribution and composition of

35

microplastics > 20 µm at the surface (0–0.2 m; bulk sample) and in the water column (3–58

36

m depth; pump) of six semi-enclosed bays and two nearshore areas of South Korea. The

37

average microplastic abundance of 41 stations at all sampling depths was 871 particles/m3,

38

and the microplastic abundance near urban areas (1051 particles/m3) was significantly higher

39

than that near rural areas (560 particles/m3). Although the average microplastic abundances in

40

the mid-column (423 particles/m3) and bottom water (394 particles/m3) were approximately 4

41

times lower than that of surface water (1736 particles/m3), microplastics prevailed throughout

42

the water column in concentrations of 10–2000 particles/m3. The average sizes of fragment

43

and fiber type microplastics were 197 µm and 752 µm, respectively. Although the polymer

44

composition differed by depth depending on the particle size and density, polypropylene and

45

polyethylene predominated throughout the water column regardless of their low density and

46

particle size. Finally, the middle and bottom water samples contained higher abundances of

47

microplastics than predicted by a model based on physical mixing, indicating that biological

48

interactions also influence the downward movement of low-density microplastics.

49 50

Keywords: FTIR, microplastic, vertical distribution, water column

2

ACS Paragon Plus Environment

Page 2 of 26

Page 3 of 26

Environmental Science & Technology

51

■ INTRODUCTION

52

Microplastics are widespread on beaches1,2 and in coastal waters,3-5 pristine areas,6,7 fresh

53

water,8,9 and open ocean.10 The annual global plastic production has increased over the last

54

six decades,11 and 4.8–12.7 million metric tons of the total 275 million metric tons of plastic

55

waste are estimated to have entered the ocean.12 Once entering marine environments, plastics

56

are weathered and fragmented via ultraviolet radiation and mechanical abrasion into micro-

57

and nano-sized particles.13,14 Moreover, reports of adverse biological effects of plastic

58

particles and fibers or additives in marine organisms are increasing.15-17

59

The main plastics (49.1%; PlasticsEurope, 2017), polyethylene (PE; 0.88–0.96 g/cm3) and

60

polypropylene (PP; 0.855–0.946 g/cm3), are less dense than seawater and many other

61

polymers [e.g., polyvinyl chloride (PVC) and polyethylene terephthalate (PET)]; therefore,

62

they can be transferred up or down the water column by vertical mixing.18-20 Vertical mixing

63

has been predicted and measured in laboratory experiments according to particle density, size,

64

and shape, as well as environmental factors.21,22 Floating plastics can also be vertically

65

transported downward from surface water in fecal pellets from zooplankton egestion21 and

66

after aggregation with organic or inorganic particles.23 Meanwhile, heavy polymers can float

67

or rise via surface tension, turbulence, and eddies. However, in situ microplastic observation

68

data (e.g., abundance, size, and polymer composition) are insufficient to understand the

69

vertical distribution and fate of microplastics in the water column. Additionally, it is difficult

70

and time-consuming to identify and confirm the polymer composition of individual particles

71

using Fourier-transform infrared spectroscopy (FTIR) or Raman spectroscopy.24,25 Studies

72

have reported an increasing number of polymers in microplastics, but data comparing the

73

polymer composition of microplastics from the water surface and water column are

74

insufficient.

75

Traditional monitoring studies have focused only on surface water,26 but further studies

76

have increasingly described the prevalence of microplastics at different depths.18-20 It is

77

difficult to determine the microplastic abundance of seawater without knowing the abundance

78

in the water column. For example, using only surface water abundance as an estimate of the

79

total abundance or contamination of microplastics in the ocean could result in underestimates,

80

while extrapolating the microplastic abundance of surface water to the whole water column

81

could result in overestimates. Several trials have attempted to estimate the total microplastic

82

abundance of seawater by integrating surface and water column abundance as predicted with 3

ACS Paragon Plus Environment

Environmental Science & Technology

83

physical mixing models based on surface water data.27 Several models evaluated with very

84

limited data based on multi-level net tows have predicted that the average concentrations of

85

buoyant microplastics are highest at the sea surface.18-20 However, such estimates have not

86

been validated or limited with in situ observations. Considering that marine organisms are

87

more abundant in the water column than in the upper 20 cm of surface water, their encounter

88

rate with microplastics could be higher in the water column than at the surface. Additionally,

89

data are insufficient for nearshore regions, which are host to high biological production that

90

could result in frequent interactions between microplastics and biota.28 Therefore, it is crucial

91

to determine the distribution and fate of microplastics in nearshore areas.

92

Manta trawls and neuston nets are frequently used for surface water sampling, as they are

93

suitable for use on vessels, have wide sampling coverage to better represent a given area, and

94

are helpful for studies of zooplankton abundance.29 However, manta trawl nets with mesh

95

sizes of 300–350 µm are not appropriate for smaller-sized particles (< 300 µm). Size is an

96

important property of microplastic particles, and is related to their stock, weathering,

97

movement, and bioavailability to marine organisms. For example, microplastic abundance

98

tends to increase with decreasing size30,31 and over 90% of detected microplastics are < 300

99

µm,30 which are easily ingested by marine invertebrates.32,33 Therefore, it is necessary to use

100

smaller mesh sizes or other sampling methods to obtain more accurate data on microplastic

101

contamination and obtain better estimates for risk assessments.

102

This study focused on the vertical distribution and composition of microplastics > 20 µm

103

in surface, middle, and bottom water from semi-enclosed bays and nearshore areas of urban

104

and rural areas in South Korea. We tested the hypotheses that (1) microplastic abundance near

105

urban areas is higher than near rural areas, (2) the abundance, polymer composition, and size

106

distribution of microplastics differ according to sampling depth, and (3) the vertical

107

distribution of microplastics cannot be completely predicted by physical mixing alone due to

108

biological interactions.

109 110

■ METHOD AND MATERIALS

111

Microplastic sampling

112

Water samples were collected in July and August of 2016 and 2017 off the coast of South

113

Korea in three rural areas [Cheonsu (CS), Hampyeong (HP), and Deungnyang (DR) Bays]

114

that are less urbanized or designated as Environmentally Preserved Areas, and five urban 4

ACS Paragon Plus Environment

Page 4 of 26

Page 5 of 26

Environmental Science & Technology

115

areas [Gwangyang (GY), Ulsan (US), and Yeongil (YI) Bays and Incheon (IC) and Busan

116

(BS) coastal areas] that are urbanized, industrialized, or designated as Special Management

117

Areas due to environmental pollution (Figure 1). Surface, mid-column (hereafter ‘middle’),

118

and bottom water samples were collected at 41 sampling stations in six bays and two coastal

119

areas. The average wind speed was 3.1 m/s (range: 1.5–7.2 m/s) during the sampling period.

120

We collected 100 L of surface water from the top 20 cm, including the surface microlayer,30

121

using a customized surface water sampler made from a stainless tray (Figure S1a). Before

122

collecting samples, the surface water sampler was washed three times with in situ seawater.

123

We also collected 100 L of middle and bottom water using a submersible water pump (PD-

124

272, Wilo; flow rate: 140 L/min) after draining water for the first 10 s at each station (Figure

125

S1b). The 100-L surface, middle, and bottom seawater samples were filtered through portable

126

hand nets (20-µm mesh) on board the vessel (Figure S1c, d). Volume-reduced samples in cod-

127

end buckets were transferred to 1-L amber glass bottles, and the top of the bottle was first

128

covered with aluminum foil before capping to avoid contamination from the plastic caps.

129

Before sampling, all glass bottles were washed and thermally treated in a furnace at 450°C

130

for 8 h. The depth of the middle sampling point was determined as the intermediate point of

131

the water depth at each station; however, in instances of thermoclines identified with a

132

conductivity, temperature, and depth system, the middle point was set to the mid-point of the

133

thermocline. The bottom water was collected approximately 1 m above the ocean floor. The

134

sampling depths of the middle and bottom layers were 3–27 m (average: 9.2 ± 6.3 m, n = 41)

135

and 5–58 m (average: 19 ± 13 m, n = 41), respectively (Table S1).

136

Sample pretreatment and identification

137

The 20-µm sieves were washed thoroughly before use via sonication and an air gun to

138

avoid cross-contamination. Volume-reduced samples were filtered through 20-µm metal

139

sieves to remove water and washed with high-performance liquid chromatography-grade pure

140

water to remove salts. Any solids remaining in sieves were transferred to a pre-weighed glass

141

beaker and dried for 24 h at 60°C in a drying oven. All organic matter in the beaker was

142

weighed and removed via wet peroxide oxidation with 35% H2O2 and Fe(II) solution at 75°C

143

(NOAA Technical Memorandum NOS-OR&R-48) (Figure S1e). After removing organic

144

matter, 6 g of NaCl was added per 20 mL of sample and mixed. The samples were transferred

145

to a glass funnel for density separation (Figure S1f). After 24 h, the settled particles were

146

drained and the supernatant was filtered through 5-µm filter paper (polycarbonate membrane 5

ACS Paragon Plus Environment

Environmental Science & Technology

147

filter paper; 47 mm Ø; Millipore). Filters were dried at room temperature and stored in glass

148

Petri dishes. Microplastic particles on the filter paper were simultaneously identified and

149

counted using a µFTIR microscope (Thermo Nicolet Continµum 6700; Thermo Scientific,

150

Waltham, MA, USA), which was used to determine the structures of molecules based on their

151

characteristic infrared radiation absorption, with the microscope used to identify smaller

152

particles. Microplastic particles were counted in 25–100% of the total filter area. The

153

analytical results for µFTIR microscope, blank samples and statistical analyses are provided

154

in the Supporting Information.

155

Vertical profile of microplastics

156

The vertical distribution of microplastics depends on oceanic turbulence induced by wind

157

and waves.18 Therefore, we assumed that the vertical profile of the particle counts per unit of

158

seawater volume (hereafter ‘abundance’) could be calculated based on the formula of

159

Kukulka et al. (2012) 18:

160

 =   , (1)

161

where z is the depth measured downward from the sea surface, N denotes the microplastic

162

abundance normalized to the abundance at the sea surface (i.e., N = 1.0 at z = 0), and w is the

163

rise velocity of microplastics. Based on laboratory experiments, Reisser et al.19 described this

164

as:

165

 = 0.002 , (2)

166

where the size and rise velocity are in units of mm and m/s, respectively.

167

Meanwhile, A0 in Eq. (1) is the vertical diffusivity, calculated as:





168

 = 1.5∗  , (3)

169

where u* denotes the frictional velocity given as u* = 0.0012 × U10, and U10 is the wind

170

speed at a height of 10 m above the sea surface (i.e., the wind speed measured at

171

approximately 7 m on the research vessel was used instead of U10 under the assumption that

172

the difference in wind speed from that at a 10-m altitude was negligible); k is the von Karman

173

constant (= 0.4); and Hs is the significant wave height, which was not observed in the present

174

survey. Therefore, we computed multiple vertical profiles using possible Hs values ranging

175

from 0 to 3 m as observed in the field.

176

■ RESULTS

177

Regional microplastic distribution

178

Microplastics were detected in all regions and stations (Table S1). The average 6

ACS Paragon Plus Environment

Page 6 of 26

Page 7 of 26

Environmental Science & Technology

179

microplastic abundances of the surface, middle, and bottom waters were representative of

180

each bay or coastal area. The mean abundances in the rural areas were 448 ± 237 (CS), 644 ±

181

82 (HP), and 588 ± 173 (DR) particles/m3, respectively, while those in the urban areas were

182

2000 ± 385 (IC), 1089 ± 283 (GY), 554 ± 273 (BS), 764 ± 304 (US), and 948 ± 103 (YI)

183

particles/m3. The mean abundance of total samples (n = 123) was 871 ± 979 particles/m3. The

184

mean abundance of microplastics in urban areas (1051 ± 571 particles/m3) was significantly

185

(p < 0.05) higher than that of rural areas (560 ± 184 particles/m3). Finally, there was a strong

186

correlation between the population of the catchments of the sampled bays and coastal area

187

(Table S2) and the average microplastic abundance at the surface (excluding middle and

188

bottom), except for the BS coastal area (Spearman’s rank, r = 0.857 and 0.893, p < 0.05, n = 7)

189

(Table S3).

190

Microplastic distribution by depth

191

The microplastic abundances in the middle (423 ± 342 particles/m3) and bottom (394 ±

192

443 particles/m3) waters were significantly lower (p < 0.05) than that of the surface water

193

(1736 ± 1179 particles/m3) in almost all study areas (Table S1 and Figure S2). As two

194

exceptions, the microplastic abundances in the middle water of one station in GY Bay located

195

in the inner bay near the harbor (980 particles/m3) and in the bottom water of one station in

196

the BS coastal area about 7.6 km from the Nakdong River (1340 particles/m3) were higher

197

than those at the surface (620 and 1120 particles/m3, respectively). The microplastic

198

abundances of the middle and bottom waters were similar. The abundance was higher in the

199

middle water than bottom water at 21 stations, and higher in the bottom water than middle

200

water at 20 stations. Overall, microplastics were found throughout the water column within

201

the range of 10–2000 particles/m3.

202

The total number of microplastics retained in water at each study area was estimated from

203

the total area (Atotal; km2) and average depth (Ds_aver) obtained within a lattice based on the

204

sampling stations in the KIOST Underway Meteorological and Oceanographic System (Table

205

S4). The total abundances of microplastics in each study area in the surface (Ms_total) and

206

water column (middle and bottom; Mc_total) were calculated as:

207 208

Ms_total = Atotal × 0.2 × Ms_aver × 106 (Eq. 4)

209

Mc_total = Atotal × (Ds_aver − 0.2) × Mc_aver × 106 (Eq. 5)

210 7

ACS Paragon Plus Environment

Environmental Science & Technology

211 212

The total numbers of microplastic residues in the whole water column at each study area are given in Table S4.

213

Microplastic size, shape, and composition

214

The detected microplastics were separated by shape into non-fibers (i.e., fragments,

215

spheres, and film) and fibers, and fractionated by size. The size distribution was determined

216

as the summed abundance of all stations (Figure 2), where the average sizes of non-fibers and

217

fibers were 197 ± 168 µm and 752 ± 711 µm, respectively. Non-fibers and fibers had

218

different size distributions. For example, non-fiber microplastics < 300 µm accounted for

219

86%, and the peak size distribution was observed in the 100–150-µm range. Among fibers,

220

the < 300-µm fraction only accounted for 30% of particles, while the peak was observed in

221

the 1000–2000-µm fraction, followed by the 200–250-µm fraction. This implies that, unlike

222

non-fibers, fibers can readily be collected using neuston nets due to their larger size.

223

Fragments were the dominant shape, accounting for an average of 81% of the particles at

224

all stations, which was followed by fibers (average abundance: 18%). In contrast, spheres and

225

films accounted for only 1%. The shape composition profiles were similar at the surface,

226

middle, and bottom, where fragments accounted for 79%, 81%, and 82%, respectively,

227

followed by fibers, which accounted for 21%, 18%, and 16%, respectively.

228

In total, 22 synthetic polymers were detected in the non-fiber-type microplastics in

229

seawater, including PP/poly(ethylene:propylene), PE, EVA, polybutyl methacrylate (PBMA),

230

polymethyl methacrylate (PMMA), PET/polyester, poly(acrylate:styrene), acrylic polymer,

231

PS, and others (e.g., polyurethane (PU), nylon, PVC, polyvinyl acetate/polyvinyl

232

chloride:vinyl acetate, polybutadiene acrylonitrile, alkyd, cellulose acetate/nitrocellulose,

233

acrylonitrile butadiene styrene, polyoxymethylene, polydimethylsiloxane, polycarbonate, and

234

epoxy/phenoxy, poly(vinyl alcohol)). Among them, PP, PE, and EVA were categorized as

235

low-density (LD) polymers, and the others were categorized as high-density (HD) polymers

236

based on their theoretical densities compared with that of seawater. Notably, expanded

237

polystyrene is a particularly LD polymer, distinguishing it from PS. It should also be noted

238

that EVA has a broad density range that depends on its vinyl acetate content; in this study, it

239

was defined as LD polymer, because five of six EVA samples were lighter than seawater

240

based on the density measurements. LD polymers were the predominant polymer type in

241

seawater, where PP accounted for an average of 41 ± 17% of samples, followed by PE (21 ±

242

15%) and EVA (19 ± 20%) (Table S5). Moreover, LD polymers were found throughout the 8

ACS Paragon Plus Environment

Page 8 of 26

Page 9 of 26

Environmental Science & Technology

243

water column.

244

In total, eight types of polymer were detected in fiber-type particles: PP, PE, polyester,

245

EVA, poly(vinyl chloride:vinyl acetate), PU, PS, and nylon. Among them, PP was

246

predominant in all regions and depths, accounting for an average of 92 ± 10% of particles,

247

followed by polyester (4.7 ± 7.7%).

248

Microplastic size and distribution by polymer type

249

Figure 3 presents the PCA results for the size difference of non-fiber microplastics

250

between the urban and rural areas. The normalized abundances of four size groups (20–100,

251

100–300, 300–500 and > 500 µm) of the 123 samples were used as the PCA input data. The

252

first two principal components (PC1 and PC2) accounted for 38.9% and 29.0% of the

253

variance, respectively. Because the size distributions of non-fiber microplastics in this study

254

were similar among all regions, the samples were not strongly separated from each other in

255

the score plot (Figure 3). However, some of the urban samples were clustered more toward

256

the left side, while the rural samples were clustered closer to the upper side of the score plot.

257

The urban samples were spread within the 20–100-µm fraction of the loading plot, while the

258

rural samples were skewed toward larger size fractions (300–500 and > 500 µm) of the

259

loading plot. However, both the urban and rural samples were distributed well in the 100–

260

300-µm fraction of the loading plot. This implied that 20–100-µm sized microplastics were

261

more prevalent in urban areas than rural areas, although the 100–300-µm fraction

262

predominated in all regions regardless of the degree of microplastic contamination.

263

The normalized abundance of four polymer types (PE, PP, EVA, and HD polymers for

264

non-fiber particles) of the 123 samples were used as PCA input data to evaluate the

265

distribution of particles by size and depth (Figure 4). PC1 and PC2 accounted for 35.4% and

266

32.6% of the variance, respectively. The distributions of the size fractions within the score

267

plot could be explained by the distribution of polymers in the loading plot. The samples were

268

separated by PC1 in the order (from left to right) 20–100, 100–300, and > 300 µm (Figure 4a).

269

This size distribution was determined by polymer type, and suggested that particles < 100 µm

270

tended to be composed of HD polymers in the water column, while those > 100 µm were

271

predominantly composed of PE and PP from the loading plot. The samples were not clearly

272

separated in the score plot by depth (Figure 4b); however, surface samples on the bottom of

273

the score plot were separated from the middle and bottom water samples along the vertical

274

line and upper side of the score plot. This implies that HD polymers tended to be distributed 9

ACS Paragon Plus Environment

Environmental Science & Technology

275

in the water column rather than in surface water, while PE and PP prevailed throughout the

276

whole water column regardless of depth.

277

Physical mixing model prediction

278

It has been hypothesized that pelagic microplastic abundance increases in deeper layers

279

with enhanced wind-induced turbulence, regardless of size (Figure S3). Hereafter, for ease of

280

interpretation, all microplastics were categorized according to their size (δ): δ < 0.3 mm, 0.3
30 m) also depended on wind speed.

296

The black and red lines in Figure S3 are superimposed over the vertical profiles calculated

297

with Eq. (1) (dotted curves) in Figure 5. In the present analysis, we used 4.2 (2.2) m/s for

298

U10, which was the average wind speed measured in each survey with wind speeds higher

299

(lower) than 3 m/s. Multiple curves were created by substituting different wave heights

300

(which were not observed in field surveys), which were unlikely to be higher than 3 m. The

301

average abundance followed the dotted curves in the uppermost layers (shallower than 5 m).

302

However, in all panels, the average abundance deviated from the dotted curves immediately

303

below the uppermost layer.

304 305 306

■ DISCUSSION Horizontal distribution of microplastics 10

ACS Paragon Plus Environment

Page 10 of 26

Page 11 of 26

Environmental Science & Technology

307

The microplastic abundance in urban areas was significantly (p < 0.05) higher and about

308

twice that in rural areas. This supports the hypothesis that urban or industrialized areas

309

discharge more microplastics than rural areas into coastal environments. A previous study

310

found a significant correlation between surface plastic concentration and coastal human

311

activity,3 supporting the results of this study. Coastal areas are adjacent not only to populated

312

areas, but also rivers, which are considered to be one of the most important input pathways

313

for plastics into the ocean.34 Additionally, nearshore coastal zones are rich in marine life,

314

supporting frequent interactions between microplastics and biota, such as ingestion, trophic

315

transfer, and sinking via biofouling and fecal pellets.28,35 However, there is a lack of data on

316

coastal areas, and few studies3-5 have investigated the abundance, spatial distribution, and

317

composition of microplastics. In contrast, many studies have sampled microplastics in

318

accumulation zones (e.g., gyres) to monitor contamination by small microplastics, and such

319

data have been used to model and predict their spatial distribution. Overall, coastal areas are

320

important sites of microplastic behavior and sources; therefore, investigations of

321

microplastics in coastal areas are necessary.

322

As expected, the microplastic abundance in surface water was significantly (p < 0.05) and

323

about 4.1 and 4.4 times higher than that in middle and bottom water, respectively. Regardless,

324

microplastics were found throughout the water column, with an average abundance of 418 ±

325

393 particles/m3 (n = 82). This was much higher than the abundances found in Mediterranean

326

coastal water (mean: 1.00 ± 1.84 particles/m3, maximum: 11.3 particles/m3),4 Hong Kong

327

(mean: 0.05–27.9 particles/m3),36 Qatar’s exclusive economic zone (mean: 0.71 particles/m3,

328

range: 0–3 particles/m3),37 and Arctic polar sub-surface water (mean: 2.68 ± 2.95 particles/m3,

329

range: 0–11.5 particles/m3).31 Even though these reported levels included microplastics
5 m) might have been

349

larger than that above the uppermost layer. This suggests that pelagic microplastics below the

350

uppermost layer are older than those in the uppermost layer and have undergone biofouling

351

processes.

352

The total number of microplastics in the surface water and the water column were

353

calculated using Eqs. (4) and (5). The results showed that there were 2–58 (20 ± 19) times

354

more particles in the water column than in surface water. These results demonstrate that a

355

large proportion of microplastics are sequestered in the water column of coastal zones, where

356

biological activity is prevalent. This is caused by vertical movement due to biological

357

interactions such as biofouling, aggregation, and egestion, as fecal pellets facilitate sinking

358

and suspension of light microplastics in the water column and bottom water. For example,

359

biofilm formation, colonization, and accumulation by microorganisms on submerged surfaces

360

affects surface hydrophobicity and decreases plastic buoyancy, increasing the sinking rate.41-

361

44

362

with waste organic matter in fecal pellets.21 Additionally, homo- or hetero-aggregation can

363

enhance the sinking rate due to the production of sticky microgels by microbes. Thus,

364

microplastic particles likely aggregate with one another or with live/dead plankton and

365

mineral particles to form marine snow (i.e., organic aggregates > 200 µm in size).45 This, in

366

turn, could increase the sinking rate, leading to the detection of even LD particles (e.g., PE

367

and PP) in the water column and sediment.46,47 Because microplastics are not limited to the

368

surface layer, monitoring of microplastics throughout the water column is necessary to

369

monitor microplastic contamination of sea areas and reduce over- or underestimations.

370

Further laboratory and field studies are urgently required to evaluate the relative contributions

Moreover, microplastics consumed and ingested by microorganisms are later egested along

12

ACS Paragon Plus Environment

Page 12 of 26

Page 13 of 26

Environmental Science & Technology

371

of various biological activities and interactions with microplastics to their vertical movement

372

and sequestration in the water column.

373

The results of the in situ observations in this study showed that the middle and bottom

374

water samples contained higher abundances of microplastics than those predicted by a

375

physical mixing model. Based on model results, Eriksen et al.48 estimated that at least 5.25

376

trillion plastic particles (0.33 to > 200 mm) were likely to be found in global oceans (North

377

Pacific, North Atlantic, South Pacific, South Atlantic, Indian Ocean, and Mediterranean Sea).

378

However, from the in situ data, we identified 13 trillion plastic particles (0.02–5 mm) in the

379

coastal area of South Korea alone (2007 km2). An average of 1.63 trillion microplastics was

380

detected from six bays and two coastal areas in this study. This difference between the model

381

prediction and in situ observation data was caused, in part, by a lack of empirical data and

382

understanding of biological processes of microplastic particles in the water column, impeding

383

the determination of microplastic abundances in the ocean. These results imply that

384

biological interactions may significantly contribute to the downward movement of

385

microplastics. This difference might also have been caused by the microplastic size range for

386

sampling and analysis. Considering only the overlapping size range of microplastics in both

387

studies of 0.33–4.75 mm, there are likely to be 4.85 trillion particles in the global ocean48 and

388

3.13 trillion particles in the Korean coastal area. The number of microplastic particles in

389

Korean coastal waters alone is comparable to that predicted for the global ocean from the

390

model. Finally, the total number of plastics in water using in situ data could be overestimated,

391

because the total microplastic number was estimated in this study using a small number of

392

samples without spatial variation in each study area. However, the model estimations were

393

calibrated against available data to help fill gaps and generate an accurate estimate.

394

Composition of microplastics

395

We identified 22 synthetic polymers in seawater by FTIR based on the measurement of

396

thousands of particles on filter papers (n = 4860), among which PP, PE, and EVA were the

397

dominant polymer types. In 2016, PP and PE were in the greatest demand and the most used

398

polymer types,11 and they have been the most commonly found polymers in seawater in many

399

other studies.5,7,39 EVA is a copolymer of ethylene and vinyl acetate used widely as a

400

thermoplastic in elastomeric materials; however, it has rarely been reported in marine

401

environments. It is used in melt adhesives and coatings,49 as the encapsulant (or pottant)

402

material in photovoltaic modules,50 in agricultural films,51 and in expanded or foam rubber 13

ACS Paragon Plus Environment

Environmental Science & Technology

403

used as equipment for various sports. Thus, EVA in marine environments is likely derived

404

from land-based sources. The EVA particles detected in seawater were fragile to even weak

405

forces, and could be readily weathered during transport into the ocean, which could explain

406

the high abundance of EVA particles (19% of non-fiber particles) in this study.

407

Among fiber particles, PP was the predominant polymer type in all regions, accounting

408

for 92% of particles. PP found as irregular white fibers was likely derived from rope debris,

409

such as aquaculture buoys, fishing nets, and ship ropes, originating from ocean activity

410

around Korea.52

411

Importance of microplastic size

412

Sampling was conducted using 20-µm mesh nets, which is close to the theoretical size

413

detection limit of FTIR spectroscopy. In this study, particles < 300 µm accounted for 86% of

414

all non-fiber particles. Among fiber particles, 71% of particles > 300 µm could be collected

415

by neuston nets. The non-fiber/fiber particle ratio differed by sampling method. For example,

416

the non-fiber/fiber ratio of samples collected with a manta trawler with a 330-µm mesh net

417

(surface water samples at 41 stations; data not shown) was lower (2.3) than that of samples

418

collected with 20-µm mesh hand nets in this study (7.8) at the same sampling stations. This

419

implies that the abundance of fragmented microplastics could be underestimated due to the

420

collection of only 14% of the total abundance of particles in the seawater because of the

421

manta net mesh size. Most studies have emphasized the importance of using mesh nets < 300

422

µm or pumps for sampling to identify small microplastics.4,31,36-40 Overall, the size detection

423

limit during sampling and analysis plays an important role in the accurate evaluation of

424

abundance and contamination of microplastics.

425

Non-fiber particles 100–300 µm in size prevailed at all stations, although the smallest

426

fraction (20–100 µm) was more prevalent in urban than rural areas (Figure 3). Moreover, this

427

size fraction tended to comprise HD polymers and was found in the water column rather than

428

floating on the surface (Figure 4), suggesting that smaller particles or plastics that are already

429

weathered and fragmented enter the ocean via sewage and rivers from urban areas.

430

Additionally, fragile polymer types that are vulnerable to weathering and fragmentation (e.g.,

431

co-polymers) are used more frequently in urban areas than rural areas due to differences in

432

the sources of microplastics from urban and rural areas. For example, a greater variety of

433

polymer types and complex polymers may be used in urban and industrialized areas, while

434

simple polymers (e.g., PP and PE) are more likely to be used in rural areas. However, 14

ACS Paragon Plus Environment

Page 14 of 26

Page 15 of 26

435

Environmental Science & Technology

additional data are required to verify the sources of microplastics by polymer type.

436

Additionally, the particle size and vertical distribution were determined by polymer type.

437

For example, the middle and bottom layers tended to contain HD polymers < 100 µm, while

438

PE and PP were the dominant polymer types for particles > 100 µm and prevailed throughout

439

the water column regardless of depth. The rise and sink velocities depend on polymer density,

440

size, and shape.40,53 For example, small microplastic particles have shorter residence times in

441

the surface layer and increased vertical distribution with decreasing size.40 We found similar

442

trends, in that small HD polymers were vertically distributed and detected throughout the

443

water column. Finally, PE and PP were the predominant polymer types throughout the water

444

column, despite their low density. This can be explained by the fact that PE and PP are the

445

most highly used polymer types, resulting in the constant supply of PE and PP microplastics

446

from land- or marine-based sources to the ocean and continuous vertical transport throughout

447

the water column due to sinking and rising.

448 449

■ ACKNOWLEDGMENTS

450

This study was supported by the Ministry of Oceans and Fisheries, Korea, under the research

451

project titled “Environmental Risk Assessment of Microplastics in the Marine Environment.”

452

AI was supported by the Environment Research and Technology Development Fund (SII-2)

453

of the Ministry of the Environment, Japan.

454 455

■ ASSOCIATED CONTENT

456

Supporting Information

457 458

The analytical results of the µFTIR microscope, blank sample analysis and statistical analyses are presented in the Supporting Information.

459

Tables describing the (1) abundance of microplastics and depth, (2) population and

460

abundance of microplastics, (3) correlation between population and microplastics, (4) coastal

461

area and average depth, and (5) composition of microplastics. Figures describing the (1) the

462

water sampler and sample treatment via images, (2) vertical distribution, and (3) vertical

463

distribution by size and wind speed.

464 465

■ REFERENCES

466

(1) Veerasingam, S.; Saha, M.; Suneel, V.; Vethamony, P.; Rodrigues, A. C.; Bhattacharyya, 15

ACS Paragon Plus Environment

Environmental Science & Technology

467

S.; Naik, B. G. Characteristics, seasonal distribution and surface degradation features of

468

microplastic pellets along the Goa coast, India. Chemosphere 2016, 159, 496–505.

469

(2) Fok, L.; Cheung, P. K.; Tang, G.; Li, W. C. Size distribution of stranded small plastic

470

debris on the coast of Guangdong, South China. Environ. Pollut. 2017, 220 (Part A), 407–412.

471

(3) Pedrotti, M. L.; Petit, S.; Elineau, A.; Bruzaud, S.; Crebassa, J. C.; Dumontet, B.; Marti,

472

E.; Gorsky, G.; Cozar, A. Changes in the floating plastic pollution of the Mediterranean Sea

473

in relation to the distance to land. Plos One 2016, 11 (8), e0161581.

474

(4) Suaria, G.; Avio, C. G.; Mineo, A.; Lattin, G. L.; Magaldi, M. G.; Belmonte, G.; Moore,

475

C. J.; Regoli, F.; Aliani, S. The Mediterranean plastic soup: synthetic polymers in

476

Mediterranean surface waters. Sci. Rep. 2016, 6, 37551.

477

(5) Frère, L.; Paul-Pont, I.; Rinnert, E.; Petton, S.; Jaffré, J.; Bihannic, I.; Soudant, P.;

478

Lambert, C.; Huvet, A. Influence of environmental and anthropogenic factors on the

479

composition, concentration and spatial distribution of microplastics: a case study of the Bay

480

of Brest (Brittany, France). Environ. Pollut. 2017, 225, 211–222.

481

(6) Lavers, J. L.; Bond, A. L. Exceptional and rapid accumulation of anthropogenic debris on

482

one of the world’s most remote and pristine islands. Proc. Natl. Acad. Sci. 2017, 114 (23),

483

6052–6055.

484

(7) Cincinelli, A.; Scopetani, C.; Chelazzi, D.; Lombardini, E.; Martellini, T.; Katsoyiannis,

485

A.; Fossi, M. C.; Corsolini, S. Microplastic in the surface waters of the Ross Sea (Antarctica):

486

occurrence, distribution and characterization by FTIR. Chemosphere 2017, 175, 391–400.

487

(8) Zhang, K.; Xiong, X.; Hu, H.; Wu, C.; Bi, Y.; Wu, Y.; Zhou, B.; Lam, P. K.; Liu, J.

488

Occurrence and characteristics of microplastic pollution in Xiangxi Bay of Three Gorges

489

Reservoir, China. Environ. Sci. Technol. 2017, 51 (7), 3794–3801.

490

(9) Anderson, P. J.; Warrack, S.; Langen, V.; Challis, J. K.; Hanson, M. L.; Rennie, M. D.

491

Microplastic contamination in Lake Winnipeg, Canada. Environ. Pollut. 2017, 225, 223–231.

492

(10) Cózar, A.; Echevarría, F.; González-Gordillo, J. I.; Irigoien, X.; Úbeda, B.; Hernández-

493

León, S.; Palma, Á. T.; Navarro, S.; García-de-Lomas, J.; Ruiz, A.; Fernández-de-Puelles, M.

494

L.; Duarte, C. M. Plastic debris in the open ocean. Proc. Natl. Acad. Sci. USA. 2014, 111 (28),

495

10239-10244.

496

(11) PlasticEurope. Plastics: the facts 2017 – an analysis of European plastics production,

497

demand and waste data. Plast. Eur. 2017, 1–44.

498

(12) Jambeck, J. R.; Geyer, R.; Wilcox, C.; Siegler, T. R.; Perryman, M.; Andrady, A.; 16

ACS Paragon Plus Environment

Page 16 of 26

Page 17 of 26

Environmental Science & Technology

499

Narayan, R.; Law, K. L. Plastic waste inputs from land into the ocean. Science 2015, 347

500

(6223), 768–771.

501

(13) Andrady, A. L. The plastic in microplastics: A review. Mar. Pollut. Bull. 2017, 119 (1),

502

12–22.

503

(14) Song, Y. K.; Hong, S. H.; Jang, M.; Han, G. M.; Jung, S. W.; Shim, W. J. Combined

504

effects of UV exposure duration and mechanical abrasion on microplastic fragmentation by

505

polymer type. Environ. Sci. Technol. 2017, 51 (8), 4368–4376.

506

(15) Hermabessiere, L.; Dehaut, A.; Paul-Pont, I.; Lacroix, C.; Jezequel, R.; Soudant, P.;

507

Duflos, G. Occurrence and effects of plastic additives on marine environments and organisms:

508

a review. Chemosphere 2017, 182, 781–793.

509

(16) Ziccardi, L. M.; Edgington, A.; Hentz, K.; Kulacki, K. J.; Kane Driscoll, S.

510

Microplastics as vectors for bioaccumulation of hydrophobic organic chemicals in the marine

511

environment: a state-of-the-science review. Environ. Toxicol. Chem. 2016, 35 (7) 1667–1676.

512

(17) Jang, M.; Shim, W. J.; Han, G. M.; Rani, M.; Song, Y. K.; Hong, S. H. Styrofoam debris

513

as a source of hazardous additives for marine organisms. Environ. Sci. Technol. 2016, 50 (10),

514

4951–4960.

515

(18) Kukulka, T.; Proskurowski, G.; Moret-Ferguson, S.; Meyer, D. W.; Law, K. L. The effect

516

of wind mixing on the vertical distribution of buoyant plastic debris. Geophys. Res. Lett. 2012,

517

39 (7), L07601; DOI 10.1029/2012GL051116.

518

(19) Reisser, J.; Slat, B.; Noble, K.; du Plessis, K.; Epp, M.; Proietti, M.; de Sonneville, J.;

519

Becker, T.; Pattiaratchi, C. The vertical distribution of buoyant plastics at sea: an

520

observational study in the North Atlantic Gyre. Biogeosciences. 2015, 12, 1249–1256.

521

(20) Brunner, K.; Kukulka, T.; Proskurowski, G.; Law, K. L. Passive buoyant tracers in the

522

ocean surface boundary layer: 2. Observations and simulations of microplastic marine debris.

523

J. Geophys. Res. Oceans 2015, 120 (11), 7559-7573.

524

(21) Cole, M.; Lindeque, P. K.; Fileman, E.; Clark, J.; Lewis, C.; Halsband, C.; Galloway, T.

525

S. Microplastics alter the properties and sinking rates of zooplankton faecal pellets. Environ.

526

Sci. Technol. 2016, 50 (6), 3239–3246.

527

(22) Kowalski, N.; Reichardt, A. M.; Waniek, J. J. Sinking rates of microplastics and

528

potential implications of their alteration by physical, biological, and chemical factors. Mar.

529

Pollut. Bull. 2016, 109 (1), 310–319.

530

(23) Long, M.; Moriceau, B.; Gallinari, M.; Lambert, C.; Huvet, A.; Raffray, J.; Soudant, P. 17

ACS Paragon Plus Environment

Environmental Science & Technology

531

Interactions between microplastics and phytoplankton aggregates: impact on their respective

532

fates. Mar. Chem. 2015, 175, 39–46.

533

(24) Löder, M. G. J.; Kuczera, M.; Mintenig, S.; Lorenz, C.; Gerdts, G. Focal plane array

534

detector-based micro-Fourier-transform infrared imaging for the analysis of microplastics in

535

environmental samples. Environ. Chem. 2015, 12 (5), 563–581.

536

(25) Primpke, S.; Lorenz, C.; Rascher-Friesenhausen, R.; Gerdts, G. An automated approach

537

for microplastics analysis using focal plane array (FPA) FTIR microscopy and image analysis.

538

Anal. Methods 2017, 9 (9), 1499–1511.

539

(26) Hidalgo-Ruz, V.; Gutow, L.; Thompson, R. C.; Thiel, M. Microplastics in the marine

540

environment: a review of the methods used for identification and quantification. Environ. Sci.

541

Technol. 2012, 46 (6), 3060–3075.

542

(27) Isobe, A.; Uchida, K.; Tokai, T.; Iwasaki, S. East Asian seas: a hot spot of pelagic

543

microplastics. Mar. Pollut. Bull. 2015, 101 (2), 618–623.

544

(28) Clark, J. R.; Cole, M.; Lindeque, P. K.; Fileman, E.; Blackford, J.; Lewis, C.; Lenton, T.

545

M.; Galloway, T. S. Marine microplastic debris: a targeted plan for understanding and

546

quantifying interactions with marine life. Front. Ecol. Environ. 2016, 14 (6), 317–324.

547

(29) Kang, J.-H.; Kwon, O.-Y.; Shim, W. J. Potential threat of microplastics to

548

zooplanktivores in the surface waters of the southern sea of Korea. Arch. Environ. Contam.

549

Toxicol. 2015, 69 (3), 340–351.

550

(30) Song, Y. K.; Hong, S. H.; Jang, M.; Kang, J. H.; Kwon, O. Y.; Han, G. M.; Shim, W. J.

551

Large accumulation of micro-sized synthetic polymer particles in the sea surface microlayer.

552

Environ. Sci. Technol. 2014, 48 (16), 9014–9021.

553

(31) Lusher, A. L.; Tirelli, V.; O’Connor, I.; Officer, R. Microplastics in Arctic polar waters:

554

the first reported values of particles in surface and sub-surface samples. Sci. Rep. 2015, 5,

555

14947.

556

(32) Van Cauwenberghe, L.; Janssen, C. R. Microplastics in bivalves cultured for human

557

consumption. Environ. Pollut. 2014, 193, 65–70.

558

(33) Van Cauwenberghe, L.; Claessens, M.; Vandegehuchte, M. B.; Janssen, C. R.

559

Microplastics are taken up by mussels (Mytilus edulis) and lugworms (Arenicola marina)

560

living in natural habitats. Environ. Pollut. 2015, 199C, 10–17.

561

(34) Horton, A. A.; Walton, A.; Spurgeon, D. J.; Lahive, E.; Svendsen, C. Microplastics in

562

freshwater and terrestrial environments: evaluating the current understanding to identify the 18

ACS Paragon Plus Environment

Page 18 of 26

Page 19 of 26

Environmental Science & Technology

563

knowledge gaps and future research priorities. Sci. Total. Environ. 2017, 586, 127–141.

564

(35) Corcoran, P. L.; Norris, T.; Ceccanese, T.; Walzak, M. J.; Helm, P. A.; Marvin, C. H.

565

Hidden plastics of Lake Ontario, Canada and their potential preservation in the sediment

566

record. Environ. Pollut. 2015, 204, 17–25.

567

(36) Tsang, Y. Y.; Mak, C. W.; Liebich, C.; Lam, S. W.; Sze, E. T. P.; Chan, K. M.

568

Microplastic pollution in the marine waters and sediments of Hong Kong. Mar. Pollut. Bull.

569

2017, 115 (1), 20–28.

570

(37) Castillo, A. B.; Al-Maslamani, I.; Obbard, J. P. Prevalence of microplastics in the marine

571

waters of Qatar. Mar. Pollut. Bull. 2016, 111 (1–2), 260–26.

572

(38) Aytan, U.; Valente, A.; Senturk, Y.; Usta, R.; Esensoy Sahin, F. B.; Mazlum, R. E.;

573

Agirbas, E. First evaluation of neustonic microplastics in Black Sea waters. Mar. Environ.

574

Res. 2016, 119, 22–30.

575

(39) Nel, H. A.; Froneman, P. W. A quantitative analysis of microplastic pollution along the

576

south-eastern coastline of South Africa. Mar. Pollut. Bull. 2015, 101 (1), 274–279.

577

(40) Enders, K.; Lenz, R.; Stedmon, C. A.; Nielsen, T. G. Abundance, size and polymer

578

composition of marine microplastics ≥ 10 µm in the Atlantic Ocean and their modelled

579

vertical distribution. Mar. Pollut. Bull. 2015, 100 (1), 70–81.

580

(41) Kooi, M.; Nes, E. H. V.; Scheffer, M.; Koelmans, A. A. Ups and Downs in the Ocean:

581

Effects of Biofouling on Vertical Transport of Microplastics. Environ. Sci. Technol. 2017, 51

582

(14), 7963-7971.

583

(42) Morét-Ferguson, S.; Law, K. L.; Proskurowski, G.; Murphy, E. K.; Peacock, E. E.;

584

Reddy, C. M. The size, mass, and composition of plastic debris in the western North Atlantic

585

Ocean. Mar. Pollut. Bull. 2010, 60 (10), 1873–1878.

586

(43) Zettler, E. R.; Mincer, T. J.; Amaral-Zettler, L. A. Life in the "Plastisphere": microbial

587

communities on plastic marine debris. Environ. Sci. Technol. 2013, 47 (13), 7137–7146.

588

(44) Kaiser, D.; Kowalski, N.; Waniek, J. J. Effects of biofouling on the sinking behavior of

589

microplastics. Environ. Res. Lett. 2017, 12 (12).

590

(45) Zhao, S. Y.; Danley, M.; Ward, J. E.; Li, D. J.; Mincer, T. J. An approach for extraction,

591

characterization and quantitation of microplastic in natural marine snow using Raman

592

microscopy. Anal. Methods 2017, 9 (9), 1470–1478.

593

(46) Matsuguma, Y.; Takada, H.; Kumata, H.; Kanke, H.; Sakurai, S.; Suzuki, T.; Itoh, M.;

594

Okazaki, Y.; Boonyatumanond, R.; Zakaria, M. P.; Weerts, S.; Newman, B. Microplastics in 19

ACS Paragon Plus Environment

Environmental Science & Technology

595

sediment cores from Asia and Africa as indicators of temporal trends in plastic pollution.

596

Arch. Environ. Contam. Toxicol. 2017, 73 (2), 230–239.

597

(47) Vianello, A.; Boldrin, A.; Guerriero, P.; Moschino, V.; Rella, R.; Sturaro, A.; Da Ros, L.

598

Microplastic particles in sediments of Lagoon of Venice, Italy: first observations on

599

occurrence, spatial patterns and identification. Estuar. Coast. Shelf S. 2013, 130, 54–61.

600

(48) Eriksen, M.; Lebreton, L. C. M.; Carson, H. S.; Thiel, M.; Moore, C. J.; Borerro, J. C.;

601

Galgani, F.; Ryan, P. G.; Reisser, J. Plastic pollution in the world's oceans: more than 5

602

trillion plastic pieces weighing over 250,000 tons afloat at sea. Plos One 2014, 9 (12),

603

e111913.

604

(49) Carraher, C. E., Jr. Introduction to Polymer Chemistry; CRC Press (Taylor & Francis

605

Group): Boca Raton, FL, 2013.

606

(50) Czanderna, A. W.; Pern, F. J. Encapsulation of PV modules using ethylene vinyl acetate

607

copolymer as a pottant: a critical review. Sol. Energy Mater. Sol. Cells. 1996, 43 (2), 101–

608

181.

609

(51) Abrusci, C.; Pablos, J. L.; Marin, I.; Espi, E.; Corrales, T.; Catalina, F. Photodegradation

610

and biodegradation by bacteria of mulching films based on ethylene vinyl acetate copolymer:

611

effect of pro-oxidant additives. J. Appl. Polym. Sci. 2012, 126 (5), 1664–1675.

612

(52) Jang, Y. C.; Lee, J.; Hong, S.; Lee, J. S.; Shim, W. J.; Song, Y. K. Sources of plastic

613

marine debris on beaches of Korea: more from the ocean than the land. Ocean Sci. J. 2014,

614

49 (2), 151–162.

615

(53) Ballent, A.; Corcoran, P. L.; Madden, O.; Helm, P. A.; Longstaffe, F. J. Sources and

616

sinks of microplastics in Canadian Lake Ontario nearshore, tributary and beach sediments.

617

Mar. Pollut. Bull. 2016, 110 (1), 383–395.

20

ACS Paragon Plus Environment

Page 20 of 26

Page 21 of 26

Environmental Science & Technology

618 619 620 621

Figure 1. Map of the locations of the surface, middle, and bottom water microplastic sampling stations in three rural (dotted line; CS, HP, and DR) and five urban (solid line; IC, GY, BS, US, and YI) areas.

21

ACS Paragon Plus Environment

Environmental Science & Technology

622 623

Figure 2. Size distribution of total (a) non-fiber and (b) fiber microplastics.

624

22

ACS Paragon Plus Environment

Page 22 of 26

Page 23 of 26

Environmental Science & Technology

625 626 627 628 629

Figure 3. PCA score and loading plots of the distribution of microplastics in urban and rural sites. The size of non-fiber particles was categorized into fractions of 20–100, 100–300, 300–500, and > 500 µm.

630

23

ACS Paragon Plus Environment

Environmental Science & Technology

631 632 633 634

Figure 4. PCA score and loading plots of (a) microplastic size (20–100, 100–300, and > 300 µm) and (b) sampling depth (surface, middle, and bottom). Four polymer types were considered (PE, PP, EVA, and HD polymers).

635

24

ACS Paragon Plus Environment

Page 24 of 26

Page 25 of 26

Environmental Science & Technology

636 637 638 639 640 641 642 643 644 645

Figure. 5 Average microplastic abundance (particle count per unit seawater volume; see Fig. S2) normalized to the abundance at the surface layer superimposed over the exponential curves calculated with Eq. (1) (dotted curves). Cases with wind speeds higher (lower) than 3 m/s are shown in the left (right) panels. The upper, middle, and lower panels show microplastics with sizes of < 0.3 mm, 0.3~0.5 mm, and 0.5~1.0 mm, respectively. The dotted curves are shown for significant wave heights (Hs; see numerals in the upper left panel) of 0.5, 1.0, 1.5, 2.0, 2.5, and 3 m.

646 647

25

ACS Paragon Plus Environment

Environmental Science & Technology

ACS Paragon Plus Environment

Page 26 of 26