Characteristics of halogenated flame retardants in the atmosphere of Dalian, China

Journal Pre-proof Characteristics of halogenated flame retardants in the atmosphere of Dalian, China Yan Wang, Yuwei Zhang, Feng Tan, Ya Yang, Zhenping Qu, Jacob Kvasnicka, Jingwen Chen PII:

S1352-2310(19)30858-1

DOI:

https://doi.org/10.1016/j.atmosenv.2019.117219

Reference:

AEA 117219

To appear in:

Atmospheric Environment

Received Date: 10 September 2019 Revised Date:

15 November 2019

Accepted Date: 9 December 2019

Please cite this article as: Wang, Y., Zhang, Y., Tan, F., Yang, Y., Qu, Z., Kvasnicka, J., Chen, J., Characteristics of halogenated flame retardants in the atmosphere of Dalian, China, Atmospheric Environment (2020), doi: https://doi.org/10.1016/j.atmosenv.2019.117219. 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.

Author Contribution Statement Yan Wang: Conceptualization, Methodology, Investigation, Resources, Data Curation, Writing - Original Draft, Supervision, Project administration, Funding acquisition Yuwei Zhang: Methodology, Validation, Formal analysis, Investigation, Data Curation, Writing - Original Draft Feng Tan: Resources, Writing - Review & Editing, Project administration Ya Yang: Validation, Formal analysis, Investigation Zhenping Qu: Resources, Writing - Review & Editing Jacob Kvasnick: Formal analysis, Writing - Review & Editing Jingwen Chen: Resources, Writing - Review & Editing, Supervision, Funding acquisition

Graphical abstract

1

Characteristics of halogenated flame retardants in the atmosphere of Dalian,

2

China

3

Yan Wang a, *, Yuwei Zhang a, Feng Tan a, Ya Yang a, Zhenping Qu a, Jacob Kvasnicka

4

b

5

a

6

School of Environmental Science and Technology, Dalian University of Technology,

7

Dalian 116024, China

8

b

, Jingwen Chen a Key Laboratory of Industrial Ecology and Environmental Engineering (MOE),

Department of Earth Sciences, University of Toronto, Toronto M5S 3B1, Canada

9 10

* Corresponding author. E-mail: [email protected]

11

1

12

Abstract

13

Samples of gas and fine particulate matter (PM2.5) were collected in Dalian,

14

China, a typical coastal city, to determine the concentrations, seasonal variations,

15

influential factors, sources, and gas-PM2.5 partitioning of polybrominated diphenyl

16

ethers (PBDEs), novel brominated flame retardants (NBFRs), and dechlorane plus

17

(DPs) in the ambient air. Annual average concentrations of Σ7PBDEs, BDE209,

18

Σ6NBFRs, and DPs were 4.40±2.93, 1460±2500, 7.81±6.85, and 0.15±0.14 pg/m3 for

19

the gas phase, and 2.68±1.64, 4291±4306, 13.6±23.4, and 0.31±0.22 pg/m3 for the

20

fine particle phase, respectively. BDE209 was the dominant congener, followed by

21

HBB and BEH-TEBP, and seasonal variations in air concentrations were apparent for

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BFRs, especially those in the gas phase. Moreover, meteorological parameters and

23

criteria air pollutants revealed significant positive correlations between temperature

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and less-brominated BFRs in the gas phase, and between PM2.5 and highly-brominated

25

BFRs in the particle phase. This suggests that the presence of these compounds in

26

ambient air may largely result from combustion-related processes. Furthermore, an

27

analysis of the gas-PM2.5 partitioning of BFRs and DPs suggested that BFRs and DPs

28

mostly attained equilibrium, except for some NBFRs. Due to the ban of commercial

29

penta-, octa-, and deca-BDEs by the Stockholm Convention, emissions from historical

30

use and combustion are becoming the important sources of PBDEs in China.

31

Keywords: Brominated flame retardants; PM2.5; Air; Meteorological conditions;

32

Gas-PM2.5 partitioning

33 2

34

1. Introduction

35

Polybrominated diphenyl ethers (PBDEs) had been extensively used as flame

36

retardants in electronic circuitries, textiles, furniture, and building materials.

37

Commercial penta-, octa-, and deca-BDEs were classified as persistent organic

38

pollutants (POPs) and banned by the Stockholm Convention for their toxicity and

39

potential for bioaccumulation and long-range transport. With the phasing out of

40

PBDEs, tons of dechlorane pluses (DPs) and novel brominated flame retardants

41

(NBFRs),

42

pentabromoethylbenzene (PBEB), bis (2,4,6-tribromophenoxy) ethane (BTBPE),

43

2-ethylhexyl

44

(2-ethylhexyl)-3,4,5,6-tetrabromophthalate (BEH-TEBP), have been extensively used

45

as substitutes (Li et al., 2015). The estimated annual production of DBDPE and

46

BTBPE is between several thousands and tens of thousands of tons (Xiong et al.,

47

2019). However, several NBFRs exhibit similar properties to POPs (Kuramochi et al.,

48

2014), being persistent, toxic, and bioaccumulative (Covaci et al., 2011). Nowadays,

49

PBDEs, NBFRs, and DPs have been frequently detected in multiple environment

50

matrices of China, such as air (Zhao et al., 2013; Ma et al., 2017), soil (Zheng et al.,

51

2015; Sun et al., 2016), and water (Moller et al., 2011; Wang et al., 2017).

such

as

hexabromobenzene

(HBB),

tetrabromobenzoate

pentabromotoluene

(EH-TBB),

(PBT),

bis

52

Air is the primary environmental matrix for semivolatile organic compounds

53

(SVOCs), and thus plays a significant role in their transport and fate. In the

54

atmosphere,

55

FR-containing materials, industrial emissions, and combustions (Odabasi et al., 2009;

these

compounds

mainly

3

originate

from

volatilization

from

56

Wang et al., 2010b). Previous studies (Wang et al., 2011; Kuramochi et al., 2014)

57

have suggested that less-brominated PBDEs in urban air were primarily from indoor

58

sources, whereas highly-brominated PBDEs were mainly from combustion-related

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sources, such as power plants and vehicles, which contain bromine in feedstock or

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fuel (Chang et al., 2014a; Chang et al., 2014b). However, the main sources of PBDEs

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in the air are still unclear, especially after the banning of commercial PBDEs. Since

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certain criteria air pollutants, such as SO2 and NO2, are indicators of fossil fuel

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combustion, an analysis of the relationship between these air pollutants and PBDEs

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may allow us to better understand sources of PBDEs in air.

65

Meteorological conditions, such as air temperature, relative humidity, wind speed

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(Li et al., 2016b), and solar irradiation (Chen et al., 2015), can significantly influence

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atmospheric concentrations, gas-PM2.5 partitioning, as well as atmospheric fates of

68

POPs. For instance, relatively high wind speed can dilute and disperse POPs in the

69

atmosphere, whereas high temperature can promote volatilization of POPs from

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various sources (Yang et al., 2013) and affect their gas-PM2.5 partitioning. Solar

71

irradiation, however, can either increase the air concentrations of POPs by increasing

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air temperature (visible light) or decrease their concentrations by promoting

73

photodegradation (UV) (Liu et al., 2015).

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Although attention has been devoted to the environmental fate of PBDEs,

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NBFRs (Covaci et al., 2011), and DPs (Ren et al., 2008) in the atmosphere, little

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information is available on seasonality and gas-PM2.5 partitioning of BFRs and DPs in

77

the air, and the potential influences of criteria air pollutants. Thus, the main objectives 4

78

of this study were to: (1) characterize the influences of meteorological factors and

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criteria air pollutants on their atmospheric levels, (2) identify their potential sources,

80

and (3) investigate their partitioning between gas phase and PM2.5.

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2. Materials and methods

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2.1 Sample collection

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Dalian is the third largest city of Northeast China and is an important center of

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both heavy and light industries. Gas and PM2.5 samples were collected separately on a

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building rooftop (~12 m high) located on the urban campus of Dalian University of

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Technology [38.886°N, 121.528°E]. A 48-hour air sample was collected from 8:00

88

AM every Monday from November 7th, 2016 to November 6th, 2017, using a

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high-volume air sampler at a sampling rate of 0.3 m3/min. Air was first passed

90

through a quartz fiber filter (Whatman, pre-baked at 450°C for 4 h), and then through

91

a polyurethane foam plug (PUF, 6.5 cm diameter × 7.5 cm high, pre-cleaned by ethyl

92

acetate and dichloromethane). In total, 52 gaseous and 52 particle air samples were

93

collected. All samples were wrapped with aluminum foil, placed into polythene

94

zip-bags, and stored at -20°C until further analysis. Meteorological parameters were

95

monitored simultaneously using a wireless weather station (DAVIS Vantage Pro2)

96

close to the air sampler (Table S1 in the Supporting Information, SI). Concentrations

97

of four Criteria Air Pollutants, including SO2, NO2, O3, and CO, were obtained from

98

an online data repository maintained by the Dalian Environmental Protection Bureau

99

(Table S2, SI). 5

100 101

2.2 Sample preparation and extraction

102

PUF plug and filter samples were spiked with surrogate standards (PCB198 and

103

PCB209, Dr. Ehrenstorfer GmbH, Germany), and extracted twice with DCM:

104

n-hexane (1:1, v/v) at 100°C for 5 min using an accelerated solvent extraction

105

(ASE350, Dionex Inc.). The extracts were concentrated under a gentle stream of

106

nitrogen to ~0.5 mL after solvent-exchange to n-hexane, and cleaned up on a silica gel

107

column containing 3 cm silica gel (3% deactivated) at the bottom, 3 cm acidic silica

108

gel (silica gel: sulfuric acid=1:1, m/m) in the middle, and topped with 0.5 cm of

109

anhydrous sodium sulfate. PBDEs were eluted with 20 mL DCM: n-hexane (1:1, v/v),

110

and finally concentrated to ~30 µL. Prior to instrumental analysis, PCB208 was added

111

as the internal standard.

112 113

2.3 Instrumental analysis

114

Agilent 6890GC-5975MS applied with a DB5-MS capillary column (30 m ×

115

0.25 mm i.d. × 0.25 µm) was used for the separation of target 8 PBDEs, 6 NBFRs,

116

and 2 DPs, including BDE28, PBT, PBEB, HBB, BDE47, BDE100, BDE99, EH-TBB,

117

BDE154, BDE153, BDE183, BTBPE, BEH-TEBP, anti-DP, syn-DP, and BDE209. 1

118

µL of each extract was injected in the splitless mode. Helium was used as the carrier

119

gas at a flow rate of 1.2 mL/min. The oven temperature program was as follows: 80°C

120

for 1 min, increased to 210°C at a rate of 20°C/min, increased to 260°C at a rate of

121

10°C/min, increased to 300°C at a rate of 15°C/min, and then held for 20 min. 6

122 123

2.4 Quality assurance and quality control (QA/QC)

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One procedural blank and one field blank were run with each batch of 10

125

samples to control potential contaminations. No target compounds were detected in

126

any blank samples, except for BDE209 (< 10%) and HBB (< 8%). The breakthrough

127

of the gaseous BFRs and DPs was tested using a second PUF plug (3.5 cm thick) in

128

series with the first one. Breakthroughs of BFRs are less than 10%. Method detection

129

limits (MDL) were calculated as the mean concentration of blanks plus three times the

130

standard deviation. The MDLs were 24.6 pg/m3 for BDE209 and 0.01-0.11 pg/m3 for

131

NBFRs, DPs, and other PBDEs. The average surrogate recoveries for PCB198 and

132

PCB209 in all samples were 93 ± 14% and 96 ± 15% for the gas phase and 87 ± 12%

133

and 84 ± 10% for the particle phase, respectively. The results were corrected by

134

blanks, but not by the surrogate recovery rates. The concentrations of target

135

compounds below the MDL were assigned zero for sums and 1/2MDL for correlation

136

analysis.

137 138

3. Results and discussion

139

3.1 Concentrations of BFRs and DPs in the air

140

The sum of BDE28, 47, 99, 100, 153, 154, and 183 is expressed as Σ7PBDEs. As

141

shown in Fig. 1 and Table S3 of SI, Σ7PBDEs in the gas phase ranged from 0.28 to

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11.6 pg/m3 with an average of 4.40 ± 2.93 pg/m3, while Σ7PBDEs in the PM2.5 ranged

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from 0.86 to 10.4 pg/m3 with an average of 2.68 ± 1.64 pg/m3. BDE28 exhibited the 7

144

highest level among those seven PBDEs in the gas phase followed by BDE47 and

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BDE183, whereas BDE183 exhibited the highest level in PM2.5 followed by BDE99

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and BDE153. Σ7PBDEs in gas phase were comparable with those (N.D.-28.8 pg/m3)

147

measured using PUF-passive air sampler in the industrial zones of Pakistan (Khan et

148

al., 2017), while Σ7PBDEs in both gas and PM2.5 (1.28-17.0 pg/m3) were also

149

comparable with those measured in urban area of Beijing (N.D.–23.6 pg/m3), China

150

(Shi et al., 2013b). The lowest concentration was discovered in the sample collected

151

during the timeframe of August 14-16, 2017 with a rainfall, while the highest

152

concentration was in the sample collected from September 4-6, 2017. The

153

concentrations of BDE209 were 26.4-15200 (average: 1460 ± 2500) pg/m3 in the gas

154

phase and 244-19600 (4290 ± 4310) pg/m3 in PM2.5. The levels of BDE209 in both

155

gas and PM2.5 in this study (707-19900 pg/m3) were much higher than those from the

156

urban area of Beijing (30.7-454 pg/m3), China (Shi et al., 2013a).

157

The total concentrations of 6 NBFRs (Σ6NBFRs) in the gas phase ranged from

158

0.27 to 25.3 (7.81 ± 6.85) pg/m3, while Σ6NBFRs in the PM2.5 ranged from 2.16 to

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132 (13.6 ± 23.4) pg/m3. The dominant compounds were HBB followed by

160

BEH-TEBP in both gas phase and PM2.5. The total concentrations of DPs were in the

161

ranges of 0.02-0.74 (0.15 ± 0.14) pg/m3 and 0.03-1.06 (0.31 ± 0.22) pg/m3 in the gas

162

phase and PM2.5, respectively. The total concentrations of NBFRs and DPs in both gas

163

and PM2.5 were over three orders of magnitude lower than those measured in the

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e-waste recycling areas of Karachi (gas and PM2.5; Σ6NBFRs (including DBDPE)

165

21.0-170 ng/m3, DPs: 15.0-85.0 ng/m3), Pakistan (Iqbal et al., 2017). Meanwhile, 8

166

levels of DPs in this study are comparable with concentrations observed in the air of

167

Atlantic Ocean (0.05-1.6 pg/m3) (Moller et al., 2012).

168 169

3.2 Compositions of BFRs and DPs in the air

170

The composition of BFRs and DPs are in the order of PBDEs > NBFRs > DPs.

171

For PBDEs, the predominant congener was BDE209 in both gas phase (98.4 ± 2.56%)

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and PM2.5 (99.8 ± 0.25%). Relatively high abundances of BDE28 (0.5 ± 0.89%) were

173

also observed in the gas phase, which can be attributed to its low molecular weight

174

and high volatility. Besides BDE209, BDE183 also exhibited relatively high

175

abundances in both gas and particle phases. Although, BDE183 is the major

176

component in the octa-BDE commercial mixture along with BDE153 and 154 (Shi et

177

al., 2013b), debromination of high brominated PBDEs, such as BDE209, may also be

178

a possible source for those compounds in the atmosphere (Gerecke et al., 2005; Ahn et

179

al., 2006). Meanwhile, HBB, a replacement of deca-BDE product, was the dominant

180

NBFR congener (36.1 ± 21.2% of NBFRs in gas phase and 72.5 ± 17.2% in PM2.5),

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followed by BEH-TEBP (gas 27.8 ± 18.7%, PM2.5 12.8 ± 12%). HBB is still produced

182

in China (Li et al., 2016a) and can also be degraded from polymeric BFRs (Moller et

183

al., 2011). For DPs, the relative abundances of syn-DP were lower than those of

184

anti-DP with the fsyn values (fsyn=syn-DP/(syn-DP+anti-DP) of 0.31±0.10 and

185

0.24±0.10 in the gas phase and PM2.5, respectively. The fsyn ratio was as slightly lower

186

than that of the commercial mixture (fsyn=0.4) (Wang et al., 2010a), suggesting a

187

fractionation of DPs in the atmosphere. 9

188 189

3.3 Seasonal variations of BFRs and DPs in the air

190

BFR concentrations in the air showed obvious seasonal variations, especially in

191

the gas phase. The average concentrations of Σ8PBDEs and Σ6NBFRs in the gas phase

192

both followed the order: summer > spring > autumn > winter. However, Σ8PBDEs in

193

PM2.5 were higher in winter than those in other seasons following the order: winter >

194

spring > summer > autumn. Meanwhile, Σ6NBFRs in PM2.5 were in the order of

195

spring > summer > autumn > winter. Not surprisingly, elevated gas-phase

196

concentrations of BFRs were observed during summer, since temperature is a major

197

factor affecting the seasonal variations of POPs in the air (Li et al., 2015). High

198

temperature may accelerate the volatilization of BFRs from various sources and from

199

fine particles, and intense solar radiation during summer may also promote

200

debromination of highly-brominated BFRs in the atmosphere (Gouin et al., 2002).

201

Meanwhile, as shown in Fig. 1, the relative proportion of PBDEs in the gas phase

202

relative to the particle phase increased with increasing temperature (Yang et al., 2012),

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especially in summer from June to August. Surprisingly, concentrations of BDE209

204

decreased in both gas and PM2.5 phases after May 22nd, 2017 especially in PM2.5,

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which may be due to the decreasing emissions from industries (may be due to the ban

206

of commercial deca-BDE). The high concentrations of Σ8PBDEs in PM2.5 in winter

207

may be due to the elevated PM2.5 and PBDE emissions from combustions such as

208

coal-heating combustion. The relatively high concentrations of Σ6NBFRs in PM2.5 in

209

spring and summer were caused by some specific emissions of HBB on March 27 and 10

210

July 17, 2017. Concentrations of DPs did not display any obvious seasonal trends,

211

which may be due to the relatively low air concentrations observed in this study.

212 213

3.4 Influences of meteorological conditions

214

In order to assess the influence of meteorological conditions on temporal trends

215

of BFRs and DPs in the atmosphere, we tested for correlations (Table 1 and Table S4,

216

SI). Temperature was significantly positively correlated (p < 0.006) with most BFRs

217

in the gas phase, including PBT, PBEB, HBB, BEH-TEBP, BDE28, 47, 100, 154, and

218

209, but negatively correlated (p < 0.04) with some BFRs in PM2.5, such as PBEB,

219

BEH-TEBP, BDE100, 99,153, and 209. This suggests that gas-PM2.5 partitioning of

220

BFRs is, to some extent, influenced by air temperature. The strong temperature

221

dependence observed for BFRs in the gas phase is similar to that observed in a

222

previous study (Li et al., 2015), which suggested that higher emissions of these

223

compounds are associated with increasing temperature. Correlations between

224

highly-brominated BFRs and temperature were weaker than those for less-brominated

225

BFRs, which may be due to their different volatilities and by their partitioning being

226

driven by physicochemical properties (Li et al., 2016b). Correlations between

227

BDE154, BEH-TEBP, BDE209 and temperature were positive for gas-phase

228

compounds but negative for these in PM2.5, suggesting that temperature significantly

229

influenced gas-PM2.5 partitioning for these three compounds. Solar radiation can

230

increase both volatilization (via increasing the temperature) and photodegradation of

231

highly-brominated PBDEs (Fang et al., 2008; Lagalante et al., 2011). Correlations 11

232

between BFRs and solar radiation were similar to those for temperature, except for

233

BDE183. Significant negative correlation (p < 0.01) was observed between solar

234

radiation and BDE183 in both gas phase and PM2.5, which suggests that influence of

235

solar radiation on the photodegradation was more important than that on the

236

volatilization for BDE183. Less-brominated BFRs in the gas phase were significantly

237

positively correlated (p < 0.05) with humidity, but negatively correlated (p < 0.05)

238

with wind speed, whereas correlations between BFRs in PM2.5 and humidity/wind

239

speed were mostly not significant. High wind speed can easily dilute the BFR

240

concentrations in the gas phase (Li et al., 2016b), but not for those in PM2.5.

241

Meanwhile, higher relative humidity may also lead to higher gas-phase concentrations

242

of POPs, since hydrophobic organic compounds have low tendencies to adsorb to

243

hydrated particles (Pankow et al., 1993). Air pressure was significantly negatively

244

correlated (p < 0.05) with most gas-phase BFRs, possibly because increased air

245

pressure may decrease the volatilization of BFRs. The influence of rainfall on air

246

concentrations of BFRs was not statistically significant, due to a limited number of

247

samples collected during rainy days.

248 249

3.5 Source apportionment

250

3.5.1 Correlations between BFR and DP congeners

251

Properties and use patterns of commercial flame retardant mixtures can influence

252

their concentrations and compositions (Ma et al., 2017), as well as their environmental

253

fates (La Guardia et al., 2006). Significant positive correlations (p < 0.047, Table S5, 12

254

SI) were observed among less-brominated BFRs, such as BDE28, 47, 100, PBT,

255

PBEB, and HBB in the gas phase (r: 0.359-0.885) or BDE28, 99, 100, PBT, PBEB,

256

and HBB in PM2.5 (r: 0.286-0.992), suggesting that they may originate from similar

257

sources and undergo similar environmental processes. A previous study (Wang et al.,

258

2017) also found a significant positive correlation between HBB and BDE47,

259

suggesting similar sources such as debromination from highly-brominated PBDEs or

260

polymeric BFRs. However, BDE99 in the gas phase only correlated with BDE100 and

261

some high BFRs such as BDE153 and BDE154, whereas BDE47 in PM2.5 had no

262

correlation with any BFRs or DPs. This interesting result suggests that BDE47 or

263

BDE99 may have other sources such as photodegradation or heterogeneous reaction.

264

Meanwhile, significant correlation was discovered between EH-TBB and BEH-TEBP,

265

which are commonly used as substitutes of penta-BDE (Covaci et al., 2011), in the

266

gas phase (p=0.034) but not in PM2.5 (p=0.065). BDE99, BDE153, and BDE154 were

267

also significantly positively correlated with each other in both the gas phase and PM2.5

268

(p < 0.001), which suggests similar sources, e.g., degradation from BDE209

269

(Kajiwara et al., 2008; Chen et al., 2015). A significant positive correlation (p < 0.05)

270

was also found between syn-DP and anti-DP, again indicating similar sources.

271 272

3.5.2 Correlations between BFRs/DPs and criteria air pollutants

273

Previous studies (Chang et al., 2014a; Chang et al., 2014b) have suggested

274

combustion or biomass burning as important sources of PBDEs. Combustion,

275

especially of fossil fuels, is also an important source of fine particles (e.g. PM2.5), SO2, 13

276

NO2, and CO in the atmosphere of China (Ding et al., 2018). To investigate the

277

potential influence of combustion on atmospheric levels of BFRs, correlations

278

between BFRs and criteria air pollutants were estimated and are shown in Table 1 and

279

Table S4, SI. Although SO2/NO2 were negatively correlated (p < 0.05) with low

280

molecular weight BFRs (BDE28, 47, 100, PBT, PBEB, and HBB) in the gas phase,

281

but positively correlated with high molecular weight BFRs in PM2.5, these may be

282

pseudo-correlations since they were both correlated with temperature. However,

283

BDE154 and BDE183 in particles were significant correlated with SO2, NO2, and CO,

284

but not with temperature, suggesting similar sources of these compounds, e.g., coal

285

combustion. The concentrations of fine particles (PM2.5, µg/m3) was significantly

286

correlated with highly-brominated BFRs such as BDE99, 100, 153, 154, 183, 209,

287

BTBPE, and BEH-TEBP in PM2.5 but not in the gas phase. This suggests that

288

increased concentration of fine particles, especially in winter, also elevated the

289

concentrations of particle-bound BFRs, which may be generated together from

290

combustions (Dong et al., 2015).

291 292

3.5.3 Principal component analysis

293

In this study, 14 BFRs, 2 DPs, 6 criteria air pollutants, and 6 meteorological

294

parameters were treated as independent variables for principle component analysis

295

(PCA). The loading plot is shown in Fig. 2. Contaminants located near each other may

296

originate from similar sources or undergo similar environmental processes. Two

297

principle components were extracted with 22% of PC1 and 21% of PC2, respectively. 14

298

Generally, variables can be divided into two main groups. Group 1 includes

299

temperature, solar irradiation, humidity, O3, and some less-brominated BFRs in the

300

gas phase, such as BDE28, 47, 100, 154, PBT, PBEB, and HBB. This implies that

301

these chemicals were significantly influenced by temperature-induced volatilization.

302

Group 2 consists of PM, SO2, NO2, CO, almost all HFRs in PM2.5 (except for BDE47

303

and HBB), and some gas-phase PBDEs (BDE99, 153, and 183). These compounds

304

may be significantly influenced by combustion and PM. TBB, DPs, and BDE209 in

305

the gas phase, which were not in these two groups, may be influenced by other

306

factors.

307 308

3.6 Gas-PM2.5 partitioning

309

Gas-particle partitioning is an important process influencing levels, transport, and

310

removal of POPs in the air (Tian et al., 2011). However, little is known of the

311

gas-particle partitioning of NBFRs, especially partitioning between the gas phase and

312

PM2.5. The measured gas-PM2.5 partition coefficients (Kp, m3/µg) and particle

313

fractions (fp) of atmospheric BFRs and DPs were calculated as follows (Pankow,

314

1994):

315

Kp = (Cp/CPM2.5)/Cg

(1)

316

fp = Cp/(Cg + Cp)

(2)

317

where CPM2.5 is the concentration of PM2.5 (µg/m3), Cp and Cg are the BFR

318

concentrations in PM2.5 and gas phase, respectively.

319

PM2.5 fractions of BFRs and DPs in the air during different seasons are shown in 15

320

Fig. 3. Generally, highly-brominated congeners are more particle-bound than

321

less-brominated ones during the same season. BDE28 (fp: 23±21%), PBT (31±29%),

322

and PBEB (30±25%) were mainly in the gas phase with syn-DP (61±20%), anti-DP

323

(68±19%), and BDE209 (63±31%) mostly in PM2.5, while the PM2.5 fractions of other

324

BFRs varied widely with sampling period. The PM2.5 fractions of most PBDEs in this

325

study are comparable with those measured in previous studies (Su et al., 2009; He et

326

al., 2019), except BDE183 and BDE209, which were lower than their results. This

327

may be because we only collected fine particles instead of total suspended particles.

328

Significant seasonality was discovered for the particle fractions of most BFRs, which

329

were much higher in winter but lower in summer than in other seasons. This may be

330

due to a strong influence of ambient temperature on their gas-particle partitioning

331

(Wong et al., 2001; Harner and Shoeib, 2002). Two exceptions are noteworthy.

332

EH-TBB and BDE153 were higher in autumn, while BDE183 and BTBPE were

333

higher in summer. Significant negative correlations (p≤0.003) were also observed

334

between the PM2.5 fractions of most BFRs and temperature, except for those four

335

BFRs. This suggests that these BFRs may be affected by certain sources or reactions.

336

For instance, as mentioned above, BDE183 in PM2.5 may be influenced by coal

337

combustion.

338

Subcooled liquid vapor pressure (PºL) and octanol-air partition coefficient (Koa)

339

have been widely used to predict gas-PM2.5 partitioning of SVOCs (Yang et al., 2018).

340

Previous studies have suggested that the logarithm of Kp generally follows a linear

341

relationship with log PºL (Pankow and Bidleman, 1991, 1992) and log Koa (Harner 16

342

and Bidleman, 1998; Pankow, 1998) under ambient temperatures and prevailing

343

particle characteristics and concentrations. The PºL and Koa values of PBDEs at 25ºC

344

shown here are based on Xu et al. (Xu et al., 2007), while the PºL and Koa values of

345

NBFRs and DPs at 25ºC were from Zhang et al (Zhang et al., 2016). As shown in Fig.

346

4, significant linear correlations were apparent for average log Kp versus log PºL (r2 =

347

0.675, p=0.0003) and log Koa (r2 = 0.631, p=0.001) for most of the BFRs and DPs,

348

except HBB and BEH-TEBP. This implies that most BFRs and DPs reach equilibrium

349

between the gas phase and fine particles. HBB and BEH-TEBP may have specific

350

sources considering their relatively high concentrations compared with other NBFRs,

351

and thus did not achieve equilibrium. The slope values are -0.191 and 0.143 for log Kp

352

vs. log PºL and log Koa respectively, which significantly differ from -1 or 1.

353

Theoretically, the slope of log Kp vs. log PºL equals -1 when chemicals reach

354

equilibrium between gas phase and PM2.5 (Pankow and Bidleman, 1992). However,

355

the slope being different to -1 may also suggest equilibrium at rural sites (Simcik et al.,

356

1998), since it can be influenced by many factors, such as ambient temperature,

357

non-exchangeability, or sampling sites (Ma et al., 2019). Smaller slopes were also

358

discovered in the urban (−0.200) and rural (−0.109) areas of Chaohu City, China (He

359

et al., 2019) and the urban areas (−0.201) of Florence, Italy (Cincinelli et al., 2014).

360 361

4. Conclusions

362

This study included a comprehensive interpretation of the characteristics,

363

influential factors, potential sources, and gas-PM2.5 partitioning of atmospheric BFRs 17

364

and DPs in Dalian, China. Significant seasonality was observed for gas-phase BFRs,

365

with higher levels apparent during summer. Meteorological conditions significantly

366

influenced the air levels of BFRs in Dalian, especially air temperature and solar

367

irradiation. Source apportionment suggested that less-brominated BFRs may originate

368

mainly from temperature-derived volatilizations or from degradation, while

369

highly-brominated BFRs may be associated with combustion or biomass burning. An

370

assessment of gas-PM2.5 partitioning suggested that most BFRs had reached

371

equilibrium, except HBB and BEH-TEBP. Despite the ban of PBDEs by the

372

Stockholm Convention, emissions from historical use or combustion are still

373

continuing, highlighting a need for further investigations.

374 375 376 377

Appendix A. Supplementary data Table S1-S5. Supplementary data associated with this article can be found in the online version.

378 379

Acknowledgements

380

This study was supported by the Key Laboratory of Coastal Environmental

381

Processes and Ecological Remediation, YICCAS (No. 2018KFJJ06), the National

382

Natural Science Foundation of China (Nos. 21976023 and 21577010), and the

383

Program of Introducing Talents of Discipline to Universities (B13012).

384 385

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538

22

539

Figures and Tables

540

Fig. 1 PBDEs, NBFRs, DPs, and BDE209 in the gas phase and PM2.5 of Dalian.

541

Fig. 2 Two-dimensional principal component loading plot of BFRs, DPs, criteria air

542

pollutants, and meteorological parameters.

543

Fig. 3 PM2.5 fractions of BFRs and DPs during different seasons.

544

Fig. 4 Liner correlations of log PºL and log Koa against average log Kp for BFRs and

545

DPs.

546 547 548

Table 1 Correlation coefficient matrix between main BFR congeners, criteria air pollutants, and meteorological parameters.

549

23

550

Fig. 1 PBDEs, NBFRs, DPs, and BDE209 in the gas phase and PM2.5 of Dalian.

551 552

24

553 554

Fig. 2 Two-dimensional principal component loading plot of BFRs, DPs, air pollutants, and meteorological parameters.

555

556 557

25

558

Fig. 3 PM2.5 fractions of BFRs and DPs during different seasons.

559 560

26

561

Fig. 4 Liner correlations of log PºL and log Koa against average log Kp for BFRs and

562

DPs.

563 564

27

565

Table 1 Correlation coefficient matrix between main BFR congeners, criteria air

566

pollutants, and meteorological parameters. BDE28

PBT

HBB BDE47 BDE100 BDE99 BDE154 BDE153 BDE183 BEH-TEBP

BDE209

Gas phase PM2.5

-0.223

0.09

-0.181

0.053

0.171

-0.264

-0.191

SO2

-.434** -.673** -.568** -.606** -.413**

.284*

-0.201

.335*

.631**

-.404**

-.344*

NO2

-.303* -.448** -.475** -.480** -.379**

0.175

-0.256

0.199

.441**

-.384**

-0.274

a

.503** .833** .739** .815** .599**

-0.01

.427**

-0.203

-.535**

.533**

.402**

.490** .658** .640** .669**

-0.168

0.265

-0.195

-.525**

0.244

.371**

T

SR

b

0.01

-.340* -0.268 -0.261

.326*

PM2.5 phase PM2.5

0.261

0.249

0.075

-0.013

.389** .576** .430**

.333*

0.204

.391**

.340*

SO2

0.246

0.201

-0.096

0.002

.502** .565** .480**

.543**

.450**

0.274

.307*

NO2

.306*

.284*

-0.063

-0.07

.596** .703** .633**

.519**

.406**

0.262

.292*

-0.226 -0.196

0.088

-0.131

-.353* -.430** -0.203

-.296*

-0.252

-.325*

-.320*

-0.192 -0.168

0.018

0.128

-.348* -.395** -0.225

-.368** -.440**

-0.111

-0.106

T

a

SR

567 568 569 570

b

*Statistically significant correlations at p < 0.05 level. **Statistically significant correlations at p < 0.01 level. a

Temperature.

b

Solar radiation.

28

Highlights Temperature, degradation, and combustion significantly affected air levels of BFRs. Gas-PM2.5 partitioning of BFRs and DPs suggested most of them reached equilibrium. PBDE emission from historical use or combustion still continues despite their ban.

Declaration of interests ☒ 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. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: