Photochemical reaction of tricresyl phosphate (TCP) in aqueous solution: Influencing factors and photolysis products

Journal Pre-proof Photochemical reaction of tricresyl phosphate (TCP) in aqueous solution: Influencing factors and photolysis products Shibin Sun, Jingqiu Jiang, Hongxia Zhao, Huihui Wan, Baocheng Qu PII:

S0045-6535(19)32210-6

DOI:

https://doi.org/10.1016/j.chemosphere.2019.124971

Reference:

CHEM 124971

To appear in:

ECSN

Received Date: 9 July 2019 Revised Date:

17 September 2019

Accepted Date: 24 September 2019

Please cite this article as: Sun, S., Jiang, J., Zhao, H., Wan, H., Qu, B., Photochemical reaction of tricresyl phosphate (TCP) in aqueous solution: Influencing factors and photolysis products, Chemosphere (2019), doi: https://doi.org/10.1016/j.chemosphere.2019.124971. 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.

Photochemical reaction of tricresyl phosphate (TCP) in aqueous solution: Influencing factors and photolysis products

Shibin Sun, 1 † Jingqiu Jiang, 1, † Hongxia Zhao, *, † Huihui Wan ‡, Baocheng Qu *,§

†

Key Laboratory of Industrial Ecology and Environmental Engineering (Ministry of

Education), School of Environmental Science and Technology, Dalian University of Technology, Dalian, 116024, China ‡

College of Chemical Engineering, Analytical Center, Dalian University of Technoloy,

Dalian 116024, China §

College of Marine Technology and Environment, Dalian Ocean University, Dalian

116024, China

#

Corresponding author phone: +86-411-84707965; Fax: +86-411-84707965;

Email: [email protected] #

Corresponding author phone: +86-411-84740281; Fax: +86-411-84740281;

Email: [email protected] 1

These authors contributed equally to this study and share first authorship

hv

0.0

directt indirectt

products

-0.4

TCP

3O

Fe3+ H2O NO2-/NO3-

2

1O

HA … 2

ln(Ct/C0)

O O O P O

-0.2

-0.6 -0.8 3+

0 µmol/L Fe 3+ 50 µmol/L Fe 3+ 10 µmol/L Fe

-1.0

· OH

-1.2 0

2

4

6 8 time (h)

10

12

1

Abstract

2

Organophosphate triesters (OPEs) have caused great concern as a class of emerging

3

environmental contaminants due to their widespread use and their toxicity to

4

organisms. However, the phototransformation behavior of OPE is still not fully

5

understood, which is important for understanding their environmental fate. In the

6

present study, the photodegradation of tricresyl phosphate (TCP), one of the most

7

widely detected OPEs in aqueous environments, was investigated including the direct

8

photolysis and in the presence of several natural water factors, NO2-, Fe3+ and humic

9

acid. The degradation process followed the pseudo-first-order kinetics, with rate

10

constant increasing slightly with increasing initial TCP concentration. The presence of

11

NO2- and Fe3+ was observed to promote the photochemical loss of TCP, while humic

12

acid played a negative role on TCP transformation. Electron spin resonance (EPR)

13

analysis showed that carbon-centered radical was produced in the photolysis process

14

of TCP, and hydroxyl radical contributed to the promotion of rate constant for Fe3+

15

and

16

HPLC-LTQ-Orbitrap MS analysis, and the possible degradation pathways of TCP

17

were proposed. These findings provide a meaningful reference for the fate and

18

transformation of OPEs in natural water.

NO2-.

Four

photolysis

products

were

tentatively

identified

by

19 20

Keywords: tricresyl phosphate (TCP); environmental factors; kinetics; radical

21

analysis; photolysis products

22 1

23

1. Introduction

24

Organophosphate triesters (OPEs) are a class of emerging environmental pollutants

25

which have been widely used as flame retardants and plasticizers in many industrial

26

and household materials, such as furniture, textiles, building materials and electronics

27

(Brandsma, et al., 2013; van der Veen, et al., 2012; Shi, et al., 2016). Because

28

polybrominated diphenyl ethers have been phased out, OPEs have become one of the

29

most frequently used alternative flame retardants. It has been reported that the annual

30

global production of OPEs currently reaches approximately 200 kt (Greaves, et al.,

31

2014), and nearly more than 70 kt being produced in China (Wei, et al., 2015). As

32

OPEs are not chemically bounded to the final products, they can be released into

33

environment via volatilization, abrasion, and leaching process (Rodriguez, et al., 2016;

34

Marvin, et al., 2016; Li et al., 2018). OPEs have been reported to be present in aquatic

35

environments including river waters, seawaters, ground waters, and even drinking

36

waters, with concentrations ranging from ng/L to ug/L (van der Veen and Boer, 2012;

37

Shi, et al., 2016; Wang et al., 2015; Cristale, et al., 2013). For example, Wang et al.

38

reported that in North China, the total concentrations of OPEs ranged from 9.6 to

39

1549 ng·L-1 in 40 major rivers draining into the Bohai Sea (Wang et al., 2015). In the

40

River Aire (UK), OPEs were detected at concentrations ranging from 6.3 to 26050

41

ng·L-1 (Cristale, et al., 2013). The ubiquitous occurrence and high levels of OPEs in

42

the water environments has sparked considerable interest of researchers.

43

An increasing number of toxicological studies have shown that OPEs have negative

44

effects on human health and are toxic to aquatic organisms (van der Veen and Boer, 2

45

2012). For instance, the chloroalkyl OPEs such as tri(2-chloroethyl) phosphate (TCEP)

46

and tri(dichloropropyl) phosphate (TDCP) have been proved to be carcinogenic and

47

neurotoxic and TCEP was considered to be environmentally persistent (Hou, et al.,

48

2016; Wang et al., 2015; Yang et al., 2014). Du et al. (2015) have reported two aryl

49

OPEs which have heart developmental toxicity by disturbing expressions of

50

transcriptional regulators in zebrafish. In addition, tricresyl phosphate (TCP) has been

51

shown to be potential thyroid hormone disruptors and could cause reproductive

52

toxicity (van der Veen and Boer, 2012; Zhang et al., 2016). Accordingly, it is essential

53

to understand the fate of OPEs in aquatic environments for their ecological risk

54

assessment.

55

Photochemical degradation is considered to be an important transformation pathway

56

of organic pollutants in aquatic environment, which may occur by either direct or

57

indirect photolysis. Direct photolysis is the result of light absorbance by pollutants

58

causing their molecular degradation. Some aryl OPEs have considerable sunlight

59

absorbance in the ultraviolet region (290-400 nm) (Cristale et al., 2017), it is believed

60

that direct photolysis plays a crucial role for the photodegradation of OPEs in aquatic

61

environment. For indirect photolysis, NO2−, Fe3+ and humic substances play crucial

62

roles, which are ubiquitous in surface water and absorb solar radiation to reach an

63

excited state, subsequently generating free radicals (Burbano et al., 2005, Cristale et

64

al., 2017). In recent years, researchers have focused on the photodegradation of OPEs

65

using advanced oxidation processes (AOPs) such as ozonation, UV/H2O2, UV/TiO2,

66

UV/persulfate (PS) for their removal in effluents (Watts and Linden 2009; 3

67

Antonopoulou et al., 2016; Antonopoulou et al., 2017; Liu et al., 2018; Ou et al., 2017;

68

Yuan et al., 2015). Nevertheless, until now, only limited studies have reported the

69

environmental fate of OPEs in natural water. Regnery and Püttmann (2010) reported

70

that upon exposure to sunlight, the concentrations of three alkyl OPEs decreased

71

significantly in lake water while no degradation was observed in ultrapure water.

72

Another study pointed out that humic acid inhibited OPEs photodegradation mediated

73

by singlet oxygen while inorganic constituents in river water enhanced their removel

74

(Cristale et al., 2017). These processes contributed the indirect photolysis of OPEs to

75

constituents in natural water. However, there are still some other constituents whose

76

effects on phototransformation of OPEs are not characterized, such as Fe3+ and NO2-.

77

Also, the photodegradation products should be paid more attention because some

78

products are more toxic than their parent compounds (Su et al., 2014).

79

To fill the knowledge gap mentioned above, photodegradation experiments were

80

performed to figure out the transformation kinetics and mechanisms of OPEs under

81

simulated solar light irradiation. TCP, one of the most widely detected OPEs in

82

aquatic environments (van der Veen and Boer, 2012), was selected as the model

83

compound. Direct photodegradation of TCP under different light intensities and

84

wavelengths were firstly studied. Then the influences of different initial

85

concentrations and various environmental factors, including Fe3+, NO2-, and humic

86

acid (HA) on the photodegradation efficiency of TCP were investigated. In addition,

87

photodegradation products of TCP after irradiation were identified and possible

88

degradation pathways were proposed. Electron paramagnetic resonance spectroscopy 4

89

(EPR) techniques was used to study the mechanism for the effects of constituents on

90

photodegradation processes and to capture the intermediates for deducing the

91

degradation pathways. These findings advance our fundamental understanding of fate

92

of OPEs in aquatic environments and ecological risk of OPEs contamination in sunlit

93

water bodies.

94 95

2. Materials and methods

96

2.1 Chemicals

97

Analytical standard TCP (mixture of isomers, CAS number: 1330-78-5, purity ≥ 99%)

98

was purchased from Aladdin Reagent (Shanghai, China), and its molecular formula

99

and weight are C21H21O4P and 368.1178 g/mol, respectively. Standard solution of TCP

100

was prepared in methanol at the concentration of 200 ppm and then stored at 4 oC in

101

the dark. HPLC grade methanol and dichloromethane (DCM) were obtained from

102

Sigma Aldrich (USA). FeCl3, NaNO2 were of reagent grade. Humic acid (CAS:

103

1415-93-6, FA ≥ 98%) was purchased from the International Humic Substance

104

Society (IHSS). Spin traps were used to capture the reactive oxygen species (ROS).

105

5,5-dimethyl-1-pyrroline-Noxide (DMPO) was obtained from Dojindo Laboratories

106

(Shanghai, China). All the solutions used in the experiments were prepared using

107

Milli-Q water (18 MΩ·cm) obtained from OKP ultrapure water system (Shanghai

108

Lake-core Instrument Co., Shanghai, China).

109 110

2.2 Irradiation 5

111

The photochemical experiments were performed in an XPA-1 photochemical reactor,

112

which the schematic diagram was shown in Figure S1 (Nanjing Xujiang

113

Electromechanical Plant, Nanjing, China). A 500 W Xe lamp, a 1000 W Xe lamp and

114

a 800 W mercury (Hg) lamp coupled with the 290 nm filters were used to obtain

115

different light intensities. The 800 W Hg lamp surrounded by 290 nm and 340 nm

116

cut-off filters were used to simulate the natural sunlight and UV-A irradiation sources,

117

and a 254 nm low-pressure Hg lamp was used as the UV-C irradiation source. The

118

light intensities in the center of the solutions were 4.67 mW/cm2, 15.52 mW/cm2 and

119

61.60 mW/cm2 for 500 W Xe lamp, 1000 W Xe lamp and 800 W Hg lamp evaluated

120

by an optical sensors (RAMSES, TriOS).

121

To keep the temperature inside the reactor stable, the lamps was enclosed in a cooling

122

well via the circulation of cold water. A 30 mL aliquot solution (50 ppb -200 ppb) was

123

placed in a quartz tube in a merry-go-round apparatus inside the reactor for irradiation.

124

The initial concentration of TCP was 100 ppb unless specified, certain concentrations

125

of FeCl3, NO2- and HA were added into the reaction solutions. Dark controls were

126

performed under the same experimental condition. At defined time intervals, samples

127

were transferred to glass vials and stored at -20

128

photochemical experiments were performed in triplicate.

o

C until analysis. All the

129 130

2.3 Analytical methods

131

Matrix matched calibration curves were prepared using Milli-Q water with TCP

132

ranging from 1 to 200 ppb. The concentration of TCP was analyzed by ultra-high 6

133

performance liquid chromatography coupled to a triple quadrupole detector

134

(UPLC-MS/MS) (TSQ Quantum Ultra, Thermo, USA). The chromatographic column

135

was a SB-C18 (2.1 mm×150 mm, particle size 5 µm, Agilent, USA) and the

136

temperature was set at 30 oC. The mobile phase was 0.2% formic acid in UPLC water

137

(15%) and methanol (85%) and the flow rate was set at 0.2 mL·min-1. The injection

138

volume was 20 µL. TCP was analyzed under positive electrospray ionization (ESI+)

139

by multiple reaction monitoring (SRM) mode. The optimized collision energy were

140

29 V for the transition of m/z 369.1 → 165.8 and 28 V for the transition of m/z 369.1

141

→243.0. All data were acquired and processed by Xcalibur software.

142

Screening of photolysis products was carried out using an LTQ Orbitrap Velos mass

143

spectrometer (Thermo Fisher Scientific, Bellefonte, PA, USA) equipped with an ESI

144

source in both positive and negative ionization mode. The MS conditions were

145

optimized as follows: sheath gas/aux gas/sweep gas 30/10/0 arb, capillary temperature

146

350 0C, capillary voltage 39 V, tube lens voltage 0 V, and spray voltage 3.5 kV. The

147

system was operated in the full spectral acquisition mode in the mass range of m/z

148

80-600 with a mass resolution of 100,000.

149

The LC system was equipped with an Ultimate XB-C18 column (2.1 mm×100 mm,

150

5µm particle, Thermo Fisher Scientific, USA) and the mobile phase was methanol (A)

151

and water (B). A gradient run was used as follows: 30% A to 60% A in 5 min, to 80%

152

A in 10 min, to 100% A in 5 min, hold 5 min, to 30% A in 5 min, equilibrate to 30% A

153

during 5 min. The flow rate was 200 µL/min and the injection volume was 5 µL. A

154

constant temperature of 30 oC was kept during analysis. All data were acquired and 7

155

processed by Xcalibur software.

156 157

2.4 Electron paramagnetic resonance (EPR) analysis

158

Experiments were still conducted in the XPA-1 photochemical reactor with the same

159

800 W Hg lamp equipped with the 290 nm cut-off filters. All the solutions were

160

prepared in the dark at room temperature (25 oC) and were loaded into high purity

161

capillary quartz tubes immediately after mixing the solution (Fe3+, NO2-, or HA) with

162

TCP and the spin trap DMPO. The final concentration of DMPO was 160 mM.

163

Samples were collected at specific irradiation time to measure the ROS signal by EPR,

164

the detailed information were shown in Supporting Information. EPR experiments

165

were performed on a Bruker EXM A-200 spectrometer (Bruker, Bermen, Germany)

166

and the operating parameters were as follows: central field, 3398 G; microwave

167

frequency, 9.45 GHz (X-band); microwave power, 1.69 Mw; scanning width, 100 G;

168

and scanning frequency, 100 kHz.Simulation of EPR data was accomplished using

169

WinSim software (NIEHS) and Bruker WinEPR. The Spin Trap Database (NIEHS)

170

was referred to in order to interpret and simulate the EPR spectra (Suh et al., 2009)

171

and the simulated spectra correlated well with the corresponding experimental spectra

172

(correlation coefficient > 0.99).

173 174

3. Results and discussion

175

3.1 UV light irradiation of TCP in milli-Q water

176

In surface waters, the photochemical transformation of pollutants could take place by 8

177

direct or indirect photoreaction. Direct photolysis take place when radiation

178

absorption by a molecule triggers its transformation. Figure S1 showed that TCP had a

179

broad absorption spectrum between 220 nm and 320 nm, and the local maximum

180

absorption wavelength was approximately 268 nm. For direct photolysis of TCP, the

181

influences of different light intensities and wavelength were evaluated. Firstly, a 500

182

W Xe lamp, 1000 W Xe lamp and 800 W Hg lamp were used as the light source, the

183

photolysis of TCP underwent with 290 nm cut-off filters and the corresponding light

184

intensities were 4.67, 15.52, 61.60 W/m2 respectively. As shown is Figure 1, the

185

degradation rate increased with the light intensity. Half-life times of 130.8 and 68.0 h

186

were obtained under 500 W Xe lamp and 1000 W Xe lamp, respectively. Under 800

187

W Hg lamp, the degradation rate was significantly increased and the half-life time

188

was 8.75 h. Dark control samples were analyzed during the same period of time and

189

the results showed no obvious degradation without exposure to UV light. The

190

irradiation spectrum of sunlight is similar with that of 1000 W Xe lamp shown in

191

Figure S3 in supporting information, and the light intensity was 20.60 W/m2 for

192

sunlight which is a litter higher than that of 1000 W Xe lamp. Thus, it is deduced the

193

half-life time of TCP for direct photolysis in natural water was close to 68.0 h,

194

meaning that the direct photolysis of TCP under sunlight plays minor role in the

195

photodegradation process in water environment, which is similar as previous study

196

(Cristale et al., 2017).

9

0.0

ln(Ct/C0)

-0.4 -0.8 -1.2

Dark control 2 4.67 mW/cm 2 15.52 mW/cm 2 61.60 mW/cm

-1.6 -2.0 0

198

5

10

15

20

25

time (h)

197

Figure 1. Photodegradation of TCP at different light intensities (C0 = 200 ppb)

199 200

An 800 W Hg arc lamp with 340 nm cut-off filter was used to simulate the UV-A light

201

and a low-pressure Hg light (254 nm) was used to verify the influence of UV-C on the

202

photodegradation of TCP. Figure 2 presented the photodegradation of TCP under

203

UV-A and UV-C irradiation in Milli-Q water. The 800 W Hg arc lamp with 290 nm

204

cut-off filter contains UV-A and UV-B region and obvious degradation was observed

205

for TCP under this condition. As shown in Figure 2, no degradation of TCP under

206

UV-A range irradiation, which indicated that UV-B plays a decisive role in the

207

photodegradation of TCP in natural environment. For UV-C region, 80% of TCP was

208

significantly removed after 20 min of irradiation. UV-C irradiation proved to be the

209

most effective light, which most probably due to its high absorbance in this region to

210

induce the direct photolysis of TCP. In the study of Cristale et al (2017), UV-C light

211

was also used to study the degradation efficiency of nine OPEs, and three of them

212

with aryl groups showed 100% removal after 10 min, which is similar with the result

213

in our study.

10

214 215

Figure 2. Photodegradation of TCP in Milli-Q water under UV-A and UV-C irradiation (C0 =

216

200 ppb)

217 218

3.2 Effects of initial concentration and typical environmental factors on the

219

phototransformation of TCP

220

The phototransformation of TCP under the simulated sunlight irradiation were further

221

investigated under various conditions with different TCP concentrations, together with

222

different concentration of Fe3+, NO2- and HA. The photodegradation rate constant and

223

half-life was determined using pseudo-first-order kinetics, C = C0e-kt. The reaction

224

rate constant (k) and the corresponding correlation coefficient (R2) were given in the

225

table S1.

11

0.0

0.0

a

-0.2

b

-0.2 -0.4 ln(Ct/C0)

ln(Ct/C0)

-0.4 -0.6 -0.8

0

2

-

0 µmol/L NO2

-

20 µmol/L NO2

-1.2 4

6 8 time (h)

10

-

100 µmol/L NO2

0

12

2

4

6 8 time (h)

10

12

0.0

0.0

c

-0.2

d

-0.2

-0.4

-0.4 ln(Ct/C0)

ln(Ct/C0)

-0.8 -1.0

50 ppb 100 ppb 200 ppb

-1.0

-0.6

-0.6 -0.8

-0.6 -0.8 0 ppm HA 2 ppm HA 10 ppm HA

3+

0 µmol/L Fe 3+ 50 µmol/L Fe 3+ 10 µmol/L Fe

-1.0 -1.2 0

2

4

-1.0 -1.2 6 8 time (h)

10

0

12

226

2

4

6 8 time (h)

10

12

227

Figure 3. The effects of environmental factors on the photodegradation of TCP (a) initial

228

concentration, (b) NO2-, (c) Fe3+, (d) HA; the concentration of TCP for the experiments in (b),

229

(c), and (d) is 100 ppb

230 231

3.2.1 Effect of initial concentration of TCP

232

Pollutant concentration may be an important factor concerning the photoreaction

233

process. As TCP was detected in natural surface waters at various concentrations

234

ranging from ppt to ppb level (Lee et al., 2016; Kim and Kannan 2018), it’s

235

significant to investigate the effect of TCP concentration on its photolysis behavior

236

under solar irradiation. In this work, the effect of initial concentration of TCP on the

237

direct degradation efficiency was investigated with three different initial

238

concentrations of 50 ppb, 100 ppb and 200 ppb. As shown in Figure 3a, the k values 12

239

increased with increasing initial concentrations of TCP, they were 0.0509 h-1 for 50

240

ppb, 0.0627 h-1 for 100 ppb and 0.0789 h-1 for 200 ppb, respectively. The

241

photodegradation half-life (t1/2) of TCP varied from 13.6 to 8.8 h with the

242

concentration ranging from 50 to 200 ppb. When the concentrations of TCP in the

243

natural waters are lower than the present study, it is expected that TCP would have a

244

longer photodegradation half-life than being discussed in this study.

245 246

3.2.2 Effect of NO2-

247

Nitrate and Nitrite are ubiquitous constituents coexisting in natural waters. The effect

248

of nitrate on the photodegradation of pollutants in water is mainly realized by the

249

production of nitrite (Beitz et al., 1999; Arakaki, 1999). When compared to nitrate,

250

nitrite absorb a larger fraction of the sunlight spectrum, making nitrite is an important

251

ROS source (Mack, 1999), which may contribute to the photodegradation of

252

pollutants. As illustrated in Figure 3b, the degradation rate of TCP was obviously

253

enhanced by the addition of NO2-, the k values were 0.072 h-1 for control, 0.0818 h-1

254

for 20 µM (NO2-), and 0.0959 h-1 for 100 µM (NO2-). The transformation rate constant

255

increased with increasing concentration of NO2-.

256

Numerous studies have shown that NO2- can generate •OH and •NO2 (Calza, et al.,

257

2012; Vione et al., 2002) under UV light irradiation through the following equations

258

(1)-(3):

259

NO2- + hv (+H+) → •NO + •O-

260

(1)

•O- + H2O → •OH + OH-

(2) 13

261

•OH + NO2- → •NO2 + OH-

(3)

262

With the increase of the concentrations of NO2-, the concentration of generated •OH

263

and •NO2 in the system also increased. The generated free radicals may attack the

264

phenyl structure (Ahn et al., 2003; Poerschmann et al., 2009), thus affecting the

265

photolysis process of TCP and accelerating the photodegradation rate of TCP in water.

266 267

3.2.3 Effect of Fe3+

268

Iron is another significant component with extensive presence in natural aquatic

269

environment at concentrations ranging from 10-7 to 10-4 M (Zhao et al., 2014).

270

Considerable literatures have proved that iron plays an important role in many

271

photochemical reactions of organic compounds relating to ROS production, such as

272

photocatalytic reaction and Fenton reaction (Voelker et al., 1997; Wang et al., 2017).

273

In this study, we used FeCl3 as the source of Fe3+ to investigate its influences on the

274

photodegradation of TCP. As illustrated in Figure 3c, the degradation rate of TCP was

275

enhanced by adding Fe3+ to the system. The k values for TCP were 0.0675 h-1 for

276

control, 0.097 h-1 for solution containing 10 µM Fe3+ and 0.0822 h-1 for solution

277

containing 50 µM Fe3+, respectively. The existing studies proved that Fe3+ could

278

produce •OH via the following reactions (Zhao et al., 2014; Peng et al., 2016; Neamtu

279

and Frimmel, 2006):

280

Fe3+ + H2O ↔ Fe(OH)2+ + H+

(4)

281

Fe(OH)2+ + hv → Fe2+ + •OH

(5)

14

282

Due to the increased •OH production with higher Fe3+ concentration, a positive role of

283

Fe3+ to the photodegradation of TCP was expected. While under our experimental

284

conditions, it’s interesting to find that although Fe3+ did enhance the degradation rate

285

of TCP at concentrations of 10 µM and 50 µM, but the degradation rate at 50 µM is

286

lower than that at 10 µM. Here, the photodegradation rate increased by 43.7% with

287

increasing Fe3+ concentration from 0 to 10 µM but decreased about 15.3% by

288

increasing Fe3+ concentration from 10 µM to 50 µM. Since the photochemical

289

properties of Fe3+ can be strongly influenced by pH levels in natural waters, the result

290

can be attributed to pH value (6.5 ± 0.2) of the solutions used in our experiments. The

291

study of Chowdhury and co-workers (2011) has demonstrated that Fe(OH)2+ is the

292

predominant photoreactive species among the Fe3+-aquo complexes. Moreover, it was

293

reported that the photoactivity of Fe(OH)2+ in aqueous solutions was restrained at pH >

294

5.0 (Zhao et al., 2014) and at a pH of 7.0 (±0.1), Fe3+ at different concentrations

295

revealed an inhibition effect (Zhou et al., 2010). Thus, that’s may be the reason that

296

TCP has a higher k value at the addition of 10 uM Fe3+ when compared to a higher

297

concentration of Fe3+.

298 299

3.2.4 Effect of HA

300

Numerous studies have demonstrated that HA play a significant role in photochemical

301

degradation of organic pollutants in aqueous systems and the dual behavior of HA as

302

photosensitizer and redox inhibitor has been proved (Yu et al., 2010). In order to

303

evaluate the effect of HA on the photodegradation of TCP, experiments without HA 15

304

and with two alternative HA concentrations (2 ppm and 10 ppm) were carried out

305

under simulated solar light irradiation. The obtained pseudo-first-order kinetic

306

degradation curve is shown in Figure 3d. According to the results, the removal rate of

307

TCP was visibly inhibited by HA, with the k values decreasing from 0.00642 h-1 for

308

control to 0.0594 h-1 for 2 ppm HA and 0.0525 h-1 for 10 ppm HA. It was obvious that

309

he presence of HA decreased the photolysis rate constant of TCP, implying HA served

310

as an inhibitor rather than a photosensitizer. Recent studies have demonstrated that

311

HA may act as a light screening agent and free radical quencher to inhibit the excited

312

triplet-induced oxidation of several organic contaminants (Calza et al., 2014; Wenk et

313

al., 2014; Koumaki et al., 2015).

314

HA/1HA*/3HA*/HA+ + •OH→ oxidized HA

315

Cristale and co-works (2017) also found that HA acted as an inhibitor for aryl

316

phosphates, for different type and concentration of HA was selected, which is in

317

consistent with this study. For aryl OPEs, photodegradation decrease in HA solution

318

can be attributed to some inhibition of excited states of photosensitizer OPEs by

319

reducing moieties of HA, because they found that sunlight absorbing OPEs showed

320

photosensitizing properties through generating singlet oxygen. In the study of

321

Kouras-Hadel et al (2012), the inhibiting effect of HA mainly attributed to reduction

322

of quinonic moieties by reaction intermediate superoxide anions.

323

Moreover, the increasing concentration of HA may increase both the generated ROS

324

level and the photoactivated HA species (1HA*, 3HA*, etc.), but the photoactivated HA

325

species are recommended to be more efficient free radical quenchers than the parent 16

326

HA (Chen et al., 2013). On the other hand, HA could absorb the sunlight effectively

327

(data shown in Figure S4), thus the inhibition could be partially related with the

328

reduction of direct light absorption of TCP due to HA scattering and light absorption

329

competition. The light screening effect and increased free radical quenching

330

efficiency of HA may led to an overall inhibition on the photodegradation of TCP.

331 332

3.2.5 Identification of free radicals

333

In this study, EPR was performed to detect •OH or other possible radicals generated

334

during the irradiation process. As seen in Figure 4, no signal was observed in any

335

solution containing DMPO under dark condition, and phosphate buffered saline (PBS)

336

showed no peaks either after 10 min of irradiation. A characteristic sextet peaks of a

337

1:1:1:1:1:1 intensity can be observed after irradiation for 5 min, which is the typical

338

signal of carbon-centered radical (Zhao et al., 2015a). The observed six-line spectrum

339

had hyperfine spiltting constants of αN = 15.78 G, αH = 23.25 G, and g value of

340

2.00298 and NoH = 0.68, where NoH is the ration of the nitrogen-spiltting constant to

341

the hydrogen-spiltting constant (Li and Chignell, 1991). This similarity of this adduct

342

and previously reported 2-chlorophenyl-DMPO adduct (αN = 15.78 G, αH = 23.25 G,

343

NoH = 0.68) (Motten et al., 1985) suggested that it was formed by the reaction of the

344

spin trap with an aryl radical generated during the photolysis of TCP. It is reported

345

that

346

2,2’,4,4’-tetrabromobiphenyl ether could generate carbon-centered radical after

347

irradiation (Zhao et al., 2015a; Zhao et al., 2015b) and sunlight absorbing aryl

some

aryl

organic

pollutants

17

such

as

bromophenol

and

348

phosphate showed photosensitizing properties (Cristale et al., 2017), thus it is

349

speculated that TCP converted to the excited state after irradiation, C-H bond

350

homogenization occurred from the benzene ring structure of the excited TCP,

351

resulting in the formation of the carbon-centered radical.

352

At the same time, the characteristic quartet peaks of the DMPO/•OH adduct with a

353

1:2:2:1 intensity was detected for TCP solution alone and TCP solutions containing

354

Fe3+, NO2- and HA after irradiation. These results are in accordance with several

355

similar studies for the DMPO/•OH adduct (Stan et al., 2005; Huang et al., 2017),

356

confirming the generation of •OH radical in this study. Take TCP solution which

357

containing100 µM NO2- as an example, simulation of the experimental spectra yielded

358

hyperfine splitting constants were: DMPO/•OH (αN = αH = 15.07 G) (see Figure 5).

359 18

360

Figure 4. EPR spectra produced by DMPO adducts in (a) TCP alone, (b) TCP + NO2- solution,

361

(c) TCP + Fe3+ solution, (d) TCP + HA solution.

362 363

Under UV irradiation, solutions containing Fe3+, NO2- and HA can be activated to

364

generate reactive species which can influence the photodegradation of organic

365

compounds in aqueous solution. As shown in Figure 4, the signal intensity of •OH

366

produced in solutions containing NO2- is higher than that in solutions containing Fe3+.

367

As discussed above, we know that the k value of TCP increased by 21.78% in the

368

presence of 50 uM Fe3+, and increased by 57.40% in the presence of 100 uM NO2-,

369

which is consistent of the •OH production in the system. In addition, the signal

370

intensity of carbon-centered radical is much higher than that in other solutions,

371

consisting with the highest degradation efficiency of TCP in NO2- solutions.

372

For TCP solution containing 10 ppm HA (Figure 4d), the •OH signals increased

373

significantly after irradiation while the photodegradation of TCP was inhibited by HA.

374

Form Figure 4d, we can see that •OH and carbon-centered radical were generated

375

after irradiation for 5 min, and less carbon-centered radicals was observed when

376

irradiation time increased to 10 min. The k value of TCP decreased by 18.22% in the

377

presence of 10 ppm HA. Form here we could conclude that HA act as a quencher to

378

inhibit OH or *HA oxidation of TCP and HA also as a light screening agent. This

379

indicated that the light competition effect of HA is too strong to cover the promotion

380

effect of •OH. These results indicated that Fe3+ and NO2- mainly promoted the

381

photodegradation of TCP by the formation of •OH after irradiation while HA mainly 19

382

competed for a light source and acted as a quencher for the reactive species, thus

383

inhibited the degradation of TCP.

384

a Experimental

b

Simulated

3340 3360 3380 3400 3420 Magnetic Field (Gauss)

385

3440

3460

386

Figure 5. Computer simulations of the EPR spectra of DMPO spin adducts after irradiation

387

for 10 min in TCP solution containing 100 µM NO2- : (a) experimental spectrum, (b)

388

composite computer-simulated spectrum;
: •OH adduct; : carbon-centered radical.

389

3.3 Identification of photochemical products

390

In order to advance the knowledge of the photolysis mechanism of TCP under the

391

simulated

392

HPLC-LTQ-Orbitrap MS. The samples of TCP in water were analyzed after 12 h

393

irradiation period. Full scan mode with m/z ranged from 50 to 600 was applied, and

394

none of the degradation products were detected in the control solutions. Due to the

395

lack of standard materials for reference, the structure of the photoproducts were

396

identified based on analyzing of the total ion chromatogram (TIC) and the exact mass

397

spectrum coupled with the molecular structure of the parent compound. A total of four

398

degradation products were detected, the corresponding MS spectra and the exacted

solar

light,

photolysis

products

20

of

TCP

were

analyzed

by

399

ion chromatogram were illustrated in Figure S5 and Figure 6, respectively. The

400

proposed elemental composition and the exact mass values of the identified products

401

during the photodegradation of TCP were summarized in Table 1. All the four

402

products had retention time lower than TCP in the chromatogram (20.42 min),

403

meaning polarity of products are higher than that of the parent compound.

404 405

Figure 6. MS spectra of four photoproducts of TCP detected by HPLC-LTQ-Orbitrap MS

406

after irradiation for 12 h.

407 408

Table 1. HPLC-LTQ-Orbitrap-MS retention times, molecular formula, accurate mass data

409

(m/z) and relative mass error (∆ (ppm)) for TCP and the identified photolysis products

compound

RT (min)

Molecular formula

m/z

∆ (ppm)

TCP

20.42

C21H21O4P

369.1250

2.44

P1

7.17

C14H15O3P

263.0832

0.76

P2

11.93

C14H15O4P

277.0635

-0.72

21

P3

13.2

C21H21O5P

383.1054

3.65

P4

8.56

C21H21O6P

401.1149

1.25

410 411

Figure 7 illustrated the possible photochemical pathways of TCP after irradiation in

412

aqueous solution. In pathway a, TCP absorbing light energy lead to the cleavage of a

413

phenoxy bond from the phosphoric center, forming the intermediate M1. Then two

414

photohydrolysis products, P1 and P2, were formed with H2O acts as attacking

415

nucleophiles. P2 is the diester phosphate acid form of TCP, and the corresponding

416

monoester was not detected in the sample of TCP solution over 12 h irradiation,

417

indicating that dicresyl phosphate was more stable than TCP after irradiation. A recent

418

study reported that the organophosphate diesters may have limited nuclear receptor

419

activity compared with the parent triesters (Kojima et al., 2016), but the toxicity

420

information of the other three photolysis products is still unavailable and need further

421

investigation.

422

After irradiation, H-abstraction by UV attacking benzene ring lead to generation of

423

carbon-centered radical (pathway b), this was confirmed by EPR results in the former

424

part. As shown in Figure 4a, •OH was also detected in the photolysis to TCP alone,

425

thus the peroxy product as a key intermediate was taken into consideration in the

426

presence of oxygen. As illustrated in Figure 7, •OH can be obtained as a decay

427

product of M2 because of its instability (Motten et al., 1985; Li and Chignell, 1987).

428

Thus, the hydroxylation products (P3 and P4) were formed during the photolysis of

429

TCP. 22

430

431 432

Figure 7. Proposed reaction pathways of TCP under simulated solar light.

433 434

Four products were characterized in the direct photolysis process of TCP. The

435

products deserve special concern as they may cause toxicity effects on the organisms

436

in water environments. Thus, for accurate ecological risk assessment of OPEs,

437

different photodegradation pathways that may lead to different photoproducts should

438

also be considered.

439 440

4 Conclusions

441

In the present study, the photodegradation of TCP was investigated in aqueous

442

solution under different UV conditions. A half-life at 67.96 h were obtained under 23

443

simulated sunlight, which means direct photolysis may account little for TCP

444

depletion. The initial concentration of TCP, and photoactive components of the

445

surface water including NO2-, Fe3+ and HA were capable of influencing the

446

phototransformation rate constant of TCP. EPR analysis showed that the

447

environmental factors could affect the photodegradation process by the involvement

448

of reactive radicals under irradiation. Carbon-centered radical and hydroxyl radical

449

were produced during the photolysis process and hydroxyl radical contributed to the

450

degradation of TCP in the presence of NO2- and Fe3+. It is the first time that photolysis

451

products of TCP were identified by HPLC-LTQ-Orbitrap MS and possible

452

degradation pathways were proposed, involving the cleavage of a phenoxy bond, C-H

453

bond homogenization from the benzene ring structure of TCP, photoinduced

454

hydrolysis and hydroxylation. Moreover, the toxicity and possible hazards of the

455

products are quite unknown and should be further studied.

456 457

Acknowledgments

458 459

This research was financially supported by National Natural Science Foundation of China (21677023).

460 461 462

24

463

References:

464

Ahn, Y.B., Rhee, S.K., Fennell, D.E., Kekhof, L.J., Hentschel, U., Häggblom, M.M.,

465

2003. Reductive dehalogenation of brominated phenolic compounds by

466

microorganisms associated with the marine sponge aplysina aerophoba. Appl.

467

Environ. Microb. 69, 4159-4166.

468

Antonopoulou, M., Karagianni, P., Konstantinou, I.K., 2016. Kinetic and mechanistic

469

study of photocatalytic degradation of flameretardant Tris (1-chloro-2-propyl)

470

phosphate (TCPP), Appl. Catal. B: Environ. 192, 152-160.

471

Antonopoulou, M., Giannakas, A., Bairamis, F., Papadaki, M., Konstantinou, I., 2017.

472

Degradation of organophosphorus flame retardant tris (1-chloro-2-propyl)

473

phosphate (TCPP) by visible light N,S-codoped TiO2 photocatalysts. Chem. Eng.

474

J. 318, 231-239.

475

Arakaki, T., 1999. pH dependent photoformation of hydroxyl radical and absorbance

476

of aqueous-phase N (III) (HNO2 and NO2-). Environ. Sci. Technol. 33,

477

2561-2565.

478

Beitz, T., Bechmann, W., Mitzner, R., 1999. Investigation on the photoreactions of

479

nitrate and nitrite ions with selected azaarenes in water. Chemosphere, 38,

480

351-361.

481

Burbano, A.A., Dionysiou, D.D., Suidan, M.T., Richardson, T.L., 2005. Oxidation

482

kinetics and effect of pH on the degradation of MTBE with Fenton reagent,

483

Water Res. 39, 107-118.

484

Brandsma, S.H. de Boer,J. Leonards, P.E. Cofino, W.P. Covaci, A., 2013.

485

Organophosphorus

flame-retardant

and

plasticizer

analysis,

including

486

recommendations from the first worldwide inter laboratory study, TrAC Trends

487

Anal. Chem. 43, 217–228.

488

Calza, P., Vione, D., Minero, C., 2014. The role of humic and fulvic acids in the

489

phototransformation of phenolic compounds in seawater. Sci. Total Environ. 493,

490

411-418.

491

Calza, P., Vione, D., Novelli, A., Pelizzetti, E., Minero, C. 2012. The role of nitrite

492

and nitrate ions as photosensitizers in the phototransformation of phenolic

493

compounds in seawater. Sci. Total Environ. 439, 67-75.

494

Chen, Y., Zhang, K., Zuo, Y., 2013. Direct and indirect photodegradation of estriol in

495

the presence of humic acid, nitrate and iron complexes in water solutions. Sci

496

Total Environ. 463-464, 802-809.

497

Chowdhury, R.R., Charpentier, P.A., Ray, M.B., 2011. Photodegradation of 25

498

17β-estradiol in aquatic solution under solar irradiation: Kinetics and influencing

499

water parameters. J. Photochem. Photobiol. A Chem. 219, 67-75.

500

Cristale, J., Katsoyiannis, A., Sweetman, A.J., Jones, K.C., Lacorte, S., 2013.

501

Occurrence and risk assessment of organophosphorus and brominated flame

502

retardants in the River Aire (UK). Environ. Pollut. 179, 194-200.

503

Cristale, J., Dantas, R.F., Luca, A.D., Sans, C., Esplugas, S., Lacorte, S., 2017. Role

504

of

oxygen

and

DOM

in

sunlight

induced

photodegradation

of

505

organophosphorous flame retardants in river water. J. Hazard. Mater. 323,

506

242-249.

507

Du, Z., Wang, G., Gao, S., Wang, Z., 2015. Aryl organophosphate flame retardants

508

induced cardiotoxicity during zebrafish embryogenesis: By disturbing expression

509

of the transcriptional regulators. Aquat. Toxicol. 161, 25-32.

510

Koumaki, E., Mamais, D., Noutsopoulos, C., Nika, M., Bletsou, A.A., Thomaidis,

511

N.S., Eftaxias, A., Stratogianni, G. 2015. Degradation of emerging contaminants

512

from water under natural sunlight: The effect of season, pH, humic acids and

513

nitrate and identification of photodegradation by-products. Chemosphere, 138,

514

675-681.

515

Greaves, A.K. Letcher, R.J., 2014. Comparative body compartment composition and

516

in ovo transfer of organophosphate flame retardants in North American Great

517

Lakes herring gulls. Environ. Sci. Technol. 48, 7942-7950.

518

Hou, R., Xu, Y., Wang, Z., 2016. Review of OPFRs in animals and humans:

519

Absorption, bioaccumulation, metabolism, and internal exposure research.

520

Chemosphere 153 (2016) 78-90.

521

Huang, J., Li, X., Ma, M., Li, D., 2017. Removal of di-(2-ethylhexyl) phthalate from

522

aqueous solution by UV/peroxymonosulfate: Influencing factors and reaction

523

pathways. Chem. Eng. J. 314, 182-191.

524

Kim, U.J., Kannan, K., 2018. Occurrence and distribution of organophosphate flame

525

retardants/plasticizers in surface waters, tap water, and rainwater – Implications

526

for human exposure. Environ. Sci. Technol. 52 (2018) 5625-5633.

527

Kojima, H., Takeuchi, S., Eede, N.V.D., Covaci, A., 2016. Effects of primary

528

metabolites of organophosphate flame retardants on transcriptional activity via

529

human nuclear receptors. Toxicol. Lett. 245, 31-39.

530

Kouras-Hadel, S., Amine-Khodja, A., Halladja, S., Richard, C., 2012. Influence of

531

humic

substance

on

the

nboflavin

532

2,4,6-trimethyphenol, J. Photochem. Photobiol. A 229, 33-38. 26

photosensitized

trandformation

of

533

Koumaki, E., Mamais, D., Noutsopoulos, C., Nika, M.C., Bletsou, A.A., Thomaidis,

534

N.S., Eftaxias, A., Stratogianni, G., 2015. Degradation of emerging contaminants

535

from water under natural sunlight: The effect of season, pH, humic acids and

536

nitrate and identification of photodegradation by-products. Chemosphere 138,

537

675-681.

538

Li, A.S.W., Chignell, C.F., 1987. Spectroscopic studies of cutaneous photosensitizing

539

agents–xii. Spin trapping study of the free radicals generated during the

540

photolysis of photo allergens bithionol and fentichlor. Photochem. Photobiol. 46,

541

445-452.

542

Li, A.S.W., Chignell, C.F., 1991. The NoH value in EPR spin trapping: a new

543

parameter for the identification of 5,5-dimethyl-1-pyrroline-N-oxide spin adducts.

544

J. Biochem. Bioph. Methods. 22, 83-87.

545

Li, C., Wei, G., J. Chen, Zhao, Y., Zhang, Y., Su, L., Qin, W., 2018. Aqueous OH

546

Radical Reaction Rate Constants for Organophosphorus Flame Retardants and

547

Plasticizers: Experimental and Modeling Studies. Environ. Sci. Technol. 52,

548

2790-2799.

549

Liu, J., Ye, J., Chen, Y., Li, C., Ou, H., 2018. UV-driven hydroxyl radical oxidation of

550

tris(2-chloroethyl) phosphate: Intermediate products and residual toxicity.

551

Chemosphere, 190, 225-233.

552

Lee, S., Jeong, W., Kannan, K., Moon, H., 2016. Occurrence and exposure assessment

553

of organophosphate flame retardants (OPFRs) through the consumption of

554

drinking water in Korea. Water Res. 103, 182-188.

555 556

Mack, J., 1999. Photochemistry of nitrite and nitrate in aqueous solution: A review. J. Photochem. Photobiol.A Chem. 128, 1-13.

557

Marvin, C.H., Sverko, E., Tomy, G.T., 2016. Analysis of Chlorinated and Phosphorus

558

Flame Retardants. In: Alaee M. (eds) Dioxin and Related Compounds. The

559

Handbook of Environmental Chemistry, pp, 411-456.

560

Motten, A.G., Buettner, G.R., Chignell, C.F., 1985. Spectroscopic studies of

561

cutaneous photosensitizing agents-VIII. A spin-trapping study of light induced

562

free radicals from chlorpromazine and promazine. Photochem. Photobiol. 42,

563

9-15.

564

Neamtu, M., Frimmel, F.H., 2006. Photodegradation of endocrine disrupting chemical

565

nonylphenol b y simulated solar UV-irradiation. Sci. Total Environ. 369,

566

295-306.

567

Ou, H., Liu, J., Ye, J., Wang, L., Gao, N., Ke, J., 2017. Degradation of 27

568

tris(2-chloroethyl) phosphate by ultraviolet-persulfate: Kinetics, pathway and

569

intermediate impact on proteome of Escherichia coli. Chem. Eng. J. 308,

570

386-395.

571

Peng, J., Wang, G., Zhang, D., Zhang, D., Li, X., 2016. Photodegradation of

572

nonylphenol in aqueous solution by simulated solar UV-irradiation: The

573

comprehensive effect of nitrate, ferric ion and bicarbonate. J. Photochem.

574

Photobiol. A: Chem. 326, 9-15.

575

Poerschmann, J., Trommler, U., Górecki, T., Kopinke, F.D., 2009. Formation of

576

chlorinated biphenyls, diphenyl ethers and benzofurans as a result of

577

Fenton-driven oxidation of 2-chlorophenol. Chemosphere, 75, 772-780.

578

Regnery J., Püttmann, W. 2010. Occurrence and fate of organophosphorus flame

579

retardants and plasticizers in urban and remote surface waters in Germany. Water

580

Res., 44, 4097-4104.

581

Rodriguez, I., Calvo, F., Quintana, J.B., Rubí, E., Rodil, R., Cela, R., 2016. Suitability

582

of solid-phase microextraction for the determination of organophosphate flame

583

retardants and plasticizers in water samples, J. Chromatogr. A, 1108, 158-165.

584

Shi, Y., Guo, L. Li, W. Wang, Y., Liu, J., Cai, Y., 2016. Occurrence, distribution and

585

seasonal variation of organophosphate flame retardants and plasticizers in urban

586

surface water in Beijing, China. Environ. Pollut. 209, 1-10.

587

Stan, S.D., Woods, J.S., Daeschel, M.A., 2005. Investigation of the presence of OH

588

radicals in electrolyzed NaCl solution by electron spin resonance spectroscopy. J

589

Agric. Food Chem. 53, 4901-4905.

590

Su, G., Crump, D., Letcher, R.J., Kennedy, S.W., 2014. Rapid in vitro metabolism of

591

the flame retardant triphenyl phosphate and effects on cytotoxicity and mRNA

592

expression in chicken embryonic hepatocytes. Environ. Sci. Technol. 48,

593

13511-13519.

594

Suh, Y.W., Buettner, G.R., Venkataraman, S., Treimer, S.E., Robertson, L.W.,

595

Ludewig, G., 2009. UVA/B-Induced formation of free radicals from

596

decabromodiphenyl ether. Environ. Sci. Technol. 43, 2581-2588.

597

van der Veen, I., Boer, J.D., 2012. Phosphorus flame retardants: Properties, production,

598

environmental occurrence, toxicity and analysis, Chemosphere 88, 1119-1153.

599

Vione, D., Maurino, V., Minero, C., Pelizzetti, E., 2002. New processes in the

600

environmental chemistry of nitrite: nitration of phenol upon nitrite photoinduced

601

oxidation. Environ. Sci. Technol. 36, 669-676.

602

Voelker, B.M., Morel, F.M.M., Sulzberger, B., 1997. Iron redox cycling in surface 28

603

waters: effects of humic substances and light. Environ. Sci. Technol. 31,

604

1004-1011.

605

Watts, M.J., Linden, K.G., 2009. Advanced oxidation kinetics of aqueous trialkyl

606

phosphate flame retardants and plasticizers. Environ. Sci. Technol. 43,

607

2937-2942.

608

Wang, Y., Feng, C., Li, Y., Gao, J., Yu, C., 2017. Enhancement of emerging

609

contaminants removal using fenton reaction driven by H2O2-producing microbial

610

fuel cells. Chem. Eng. J. 307, 679-686.

611

Wang, R., Tang, J., Xie, Z., Mi, W., Chen, Y., Wolschke, H., Tian, C., Pan, X., Luo, Y.,

612

Ebinghaus, R., 2015. Occurrence and spatial distribution of organophosphate

613

ester flame retardants and plasticizers in 40 rivers draining into the Bohai Sea,

614

north China. Environ. Pollut. 198, 172-178.

615

Wang, Q., Lai, N.L., Wang, X., Guo, Y., Lam, P.K., Lam, J.C., Zhou, B., 2015.

616

Bioconcentration

and

transfer

of

the

organophorous

flame

retardant

617

1,3-Dichloro-2-propyl phosphate causes thyroid endocrine disruption and

618

developmental neurotoxicity in zebrafish larvae. Environ. Sci. Technol. 49,

619

5123-5132.

620

Wei, G., Li, D., Zhuo, M., Liao, Y., Xie, Z., Guo, T., Li, J., Zhang, S., Liang, Z., 2015.

621

Organophosphorus flame retardants and plasticizers: Sources, occurrence,

622

toxicity and human exposure, Environ. Pollut. 196, 29-46.

623

Wenk, J., Eustis, S.N., McNeill, K., Canonica, S., 2013. Quenching of excited triplet

624

states by dissolved natural organic matter. Environ. Sci. Technol. 47,

625

12802-12810.

626 627

Yang, F., Ding, J., Huang, W., Xie, W., Liu, W., 2014. Particle size-specific

628

distributions and preliminary exposure assessments of organophosphate flame

629

retardants in office air particulate matter. Environ. Sci. Technol. 48, 63-70.

630

Yu, C., Zhang, Y. Quan, X., Chen, S., Han, J., Ou, X., Zhao, J., 2010. Photochemical

631

effect of humic acid components separated using molecular imprinting method

632

applying porphyrin-like substances as templates in aqueous solution. Environ.

633

Sci. Technol. 44, 5812-5817.

634

Yuan, X., Lacorte, S., Cristale, J., Dantas, R.F., Sans, C., Esplugas, S., Qiang, Z., 2015.

635

Removal of organophosphate esters from municipal secondary effluent by ozone

636

and UV/H2O2 treatments. Sep. Purif. Technol. 156, 1028-1034.

637

Zhang, Q., Ji, C., Yin, X., Yan, Lu, L., Zhao, M., 2016. Thyroid hormone-disrupting 29

638

activity and ecological risk assessment of phosphorus-containing flame

639

retardants by in vitro, in vivo and in silico approaches. Environ. Pollut. 210,

640

27-33.

641

Zhao, Q., Zhao, H., Quan, X., Chen, S., Zhang, Y., 2014. Photochemical

642

transformation of 2,2′,4,4′-tetrabromodiphenyl ether (BDE-47) in surface coastal

643

waters: Effects of chloride and ferric ions. Mar. Pollut. Bull. 86, 76-83.

644

Zhou, D., Huang, W., Wu, F., Han, C., Chen, Y., 2010. Photodegradation of

645

chloromycetin in aqueous solutions: kinetics and influencing factors. React.

646

Kinet. Mech. Cat. 100, 45-53.

647

Zhao, H., Jiang, J., Wang, Y., Lehmler, H., Buettner, G.R., Quan, X., Chen, J., 2015a.

648

Monohydroxylated

649

dihydroxylated polybrominated biphenyls (Di-OH-PBBs): Novel photoproducts

650

of 2,6-dibromophenol. Environ. Sci. Technol., 49, 14120-14128.

651

polybrominated

diphenyl

ethers

(OH-PBDEs)

and

Zhao, Q., Zhao, H., Quan, X., He, X., Chen, S., 2015b. Photochemical formation of

652

hydroxylated

polybrominated

diphenyl

653

polybrominated diphenyl ethers (PBDEs) in aqueous solution under simulated

654

solar light irradiation. Environ. Sci. Technol. 49, 9092-9099.

655

30

ethers

(OH-PBDEs)

from

Highlights Direct and indirect photolysis of TCP in water were investigated under irradiation. EPR was used for deducing effects of Fe3+, NO2- and HA on phototransformation of TCP. Carbon-centered radical and ·OH were formed during the photolysis process of TCP. Four photoproducts were identified by HPLC-LTQ-Orbitrap MS analysis.