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Chlorination of bisphenol S: Kinetics, products, and effect of humic acid
Accepted Manuscript Chlorination of bisphenol S: Kinetics, products, and effect of humic acid Yuan Gao, Jin Jiang, Yang Zhou, Su-Yan Pang, Jun Ma, Chengchun Jiang, Yue Yang, Zhuang-song Huang, Jia Gu, Qin Guo, Jie-Bin Duan, Juan Li PII:
S0043-1354(17)31044-8
DOI:
10.1016/j.watres.2017.12.049
Reference:
WR 13447
To appear in:
Water Research
Received Date: 9 September 2017 Revised Date:
18 December 2017
Accepted Date: 19 December 2017
Please cite this article as: Gao, Y., Jiang, J., Zhou, Y., Pang, S.-Y., Ma, J., Jiang, C., Yang, Y., Huang, Z.-s., Gu, J., Guo, Q., Duan, J.-B., Li, J., Chlorination of bisphenol S: Kinetics, products, and effect of humic acid, Water Research (2018), doi: 10.1016/j.watres.2017.12.049. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. 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.
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Chlorination of Bisphenol S: Kinetics, Products, and
2
Effect of Humic Acid
3
Yuan Gaoa, Jin Jianga,*, Yang Zhoua, Su-Yan Pangb,*, Jun Maa, Chengchun Jiangc,
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Yue Yangd, Zhuang-song Huanga, Jia Gua, Qin Guod, Jie-Bin Duand, and Juan Lia
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a
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Municipal and Environmental Engineering, Harbin Institute of Technology, Harbin
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150090, China
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b
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State Key Laboratory of Urban Water Resource and Environment, School of
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School of Municipal and Environmental Engineering, Jilin Jianzhu University,
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Changchun 130118, China
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c
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518055, China
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d
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and Technology, Harbin 150040, China
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*Corresponding Author: Prof. Jin Jiang, E-mail: [email protected];
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*Corresponding Author: Prof. Su-Yan Pang, E-mail: [email protected]
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College of Chemical and Environmental Engineering, Harbin University of Science
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School of Civil and Environmental Engineering, Shenzhen Polytechnic, Shenzhen
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Abstract
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Bisphenol S (BPS), as a main alternative of bisphenol A for the production of
20
industrial and consumer products, is now frequently detected in aquatic environments.
21
In this work, it was found that free chlorine could effectively degrade BPS over a
22
wide pH range from 5-10 with apparent second-order rate constants of 7.6-435.3
23
M−1s−1.
24
mono/di/tri/tetrachloro-BPS), 4-hydroxybenzenesulfonic acid (BSA), chlorinated
25
BSA (mono/dichloro-BSA), 4-chlorophenol (4CP), and two polymeric products were
26
detected
27
ionization-tandem quadrupole time-of-flight mass spectrometry. Two parallel
28
transformation pathways were tentatively proposed: (i) BPS was attacked by stepwise
29
chlorine electrophilic substitution with the formation of chlorinated BPS. (ii) BPS was
30
oxidized by chlorine via electron transfer leading to the formation of BSA, 4CP and
31
polymeric products. Humic acid (HA) significantly suppressed the degradation rates
32
of BPS even taking chlorine consumption into account, while negligibly affected the
33
products species. The inhibitory effect of HA was reasonably explained by a
34
two-channel kinetic model. It was proposed that HA negligibly influenced pathway i
35
while appreciably inhibited the degradation of BPS through pathway ii, where HA
36
reversed BPS phenoxyl radical (formed via pathway ii) back to parent BPS.
37
Keywords: Bisphenol S; Chlorine; Humic acid; Electrophilic substitution; Electron
38
transfer
total
of
eleven
products
including
chlorinated
BPS
(i.e.,
high
performance
liquid
chromatography
and
electrospray
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1. Introduction
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Due to the widespread occurrence of bisphenol A (BPA) and its adverse effect on
41
both human and ecosystem health, organizations such as the United States
42
Environmental Protection Agency (USEPA) and the European Food Safety Authority
43
(EFSA) established a limit to BPA (Barroso 2011, Staples et al. 1998, Vandenberg et
44
al. 2007). In response to these restrictions and public pressure, bisphenol S (BPS;
45
4,4’-sulfonyldiphenol) is gradually used in replacement of BPA. BPS is commonly
46
used in epoxy glues, canned coatings, foodstuffs, and paper products (Naderi et al.
47
2014). Therefore, the occurrence of BPS in the aquatic environments has been
48
documented in recent years (Liao et al. 2012, van Leerdam et al. 2014, Yamazaki et
49
al. 2015, Yang et al. 2014). For instance, Yamazaki et al. (2015) reported the
50
occurrence of BPS as high as 6840 ng/L in surface water and seawater of Japan,
51
China, Korea and India. Liao et al. (2012) reported that BPS was present in the
52
sediment of United States, Japan, and Korea up to the concentration of 1970 ng/g dry
53
weight. Unfortunately, several studies have reported that BPS has similar estrogenic
54
activity and appears to be more resistant to environmental degradation as compared to
55
BPA (Danzl et al. 2009, Hashimoto et al. 2001, Rochester and Bolden 2015).
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Chlorine is a globally most used chemical for water disinfection. In addition, it
57
has been well documented that chlorine can react with a wide range of organic
58
contaminants especially phenolic compounds (Deborde et al. 2004, Deborde and Von
59
Gunten 2008, Dodd et al. 2005, Dodd and Huang 2007, Gallard and von Gunten
60
2002a, b, Gallard et al. 2004, Gao et al. 2016, Rebenne et al. 1996). For instance, 3
ACCEPTED MANUSCRIPT Gallard et al. (2004) reported that BPA could be appreciably degraded by chlorine
62
with a second-order rate constant of 58 M-1 s-1 at pH 7.0 (at 20 oC), where
63
chlorinated-BPA was generated via stepwise electrophilic substitution. In a very
64
recent work, we found that chlorine could rapidly oxidize tetrabromobisphenol A
65
(TBrBPA) via electron transfer with a second-order rate constant of 1360 M−1 s−1 at
66
pH 7.0 (at 25 oC), where oxidative product 2,6-dibromo-4-hydroxycumyl alcohol was
67
predominantly generated (Gao et al. 2016, Lin et al. 2009a, Yang et al. 2014).
68
However, the reactions of chlorine with BPS, structurally similar to BPA and
69
TBrBPA (see Table S1 for their chemical structures), have not been characterized so
70
far.
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Dissolved organic matter (DOM), ubiquitously existing in diverse aquatic
72
environments, may exert important impacts on the transformation of contaminants in
73
natural environments and engineered processes. As a competitor for oxidant, DOM
74
can suppress the degradation of contaminants in numerous chemical oxidation
75
processes (Fang et al. 2014, Gallard et al. 2004, Li et al. 2017, Lu et al. 2015, Luo et
76
al. 2016, Sharma et al. 2015). Another inhibitory effect of DOM has been reported to
77
take place in excited triplet states, permanganate, ferrate or enzymatic catalysis
78
oxidation (Canonica and Laubscher 2008, Feng et al. 2013, Gao et al. 2016, Leresche
79
et al. 2016, Lu et al. 2015, Vione et al. 2017, Wenk et al. 2011, Wenk et al. 2015),
80
where DOM can reduce the reactive intermediates formed via one electron-transfer
81
back to parent contaminants. Interestingly, in our recent work, this inhibitory effect of
82
DOM was also observed in chlorination of TBrBPA while not in chlorination of BPA
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(Gao et al. 2016). The contrasting effects might be related to the distinct pathways
84
involved in chlorination of BPA vs TBrBPA (i.e., electrophilic substitution for BPA
85
vs electron transfer for TBrBPA) (Gao et al. 2016). In this work, the transformation kinetics and products of BPS by chlorine as well
87
as the effect of HA were investigated for the first time. Firstly, reaction kinetics were
88
studied in synthetic buffered waters over pH range of 5-10. Secondly, transformation
89
products of BPS by chlorine were identified by a high performance liquid
90
chromatography and electrospray ionization-tandem quadrupole time-of-flight mass
91
spectrometry (HPLC/ESI-QTOF-MS), and the tentative pathways were proposed.
92
Finally, the effects of HA on the transformation of BPS by chlorine were investigated.
93
2. Experimental Section
94
2.1. Materials.
95
BPS,
96
2,2-azino-bis(3-ethylbenzothiazoline)-6-sulfonic acid diammonium (ABTS) were
97
purchased from Sigma-Aldrich. Sodium hypochlorite and sodium thiosulfate were
98
purchased from Sinopharm Chemical Reagent Co. Ltd., China. All reagents used were
99
of 97% purity or higher without further purification unless otherwise stated. Solutions
100
were prepared in deionized water (18.2 MΩcm) from a Milli-pore system. The stock
101
solutions of chlorine were prepared by diluting a commercial solution of sodium
102
hypochlorite (NaClO, 4% active chlorine) and standardized by iodometry. The stock
103
solutions of HA were purified by repeated pH adjustment, filtration and precipitation
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acid
(HA;
surrogate
of
DOM),
2-methoxyphenol,
and
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following the procedure described in our previous work and its concentration was
105
measured in mgC/L (Gao et al. 2016, Rebhun et al. 1998).
106
2.2. Experimental procedure. Kinetic studies were performed in 50 mL conical flasks under constant stirring at
108
25(±2) oC. Reactions were initiated by adding chlorine in excess (10-400 µM) into
109
pH-buffered solutions (10 mM phosphate buffer for pH 5-10) containing BPS (1 µM)
110
with/without HA (0.5-2 mgC/L). At a specific time interval, two parallel samples
111
were withdrawn, and one was quenched by thiosulfate to measure residual BPS and
112
the other was quenched by ABTS to measure residual chlorine (Pinkernell et al. 2000,
113
Song et al. 2015). The changes of solution pH were negligible (< 0.1) during the
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kinetic runs. All the kinetic experiments were performed in triplicates and average
115
data were presented. The relative standard deviations were always <10% unless
116
otherwise stated.
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For products identification, a series of pH-buffered (pH 7) solutions containing
118
BPS (at a relatively high concentration of 10 µM) with/without HA (0.5-5 mg C/L)
119
were prepared and treated by chlorine at various doses (5-50 µM). The resulting
120
solutions were analyzed by HPLC/ESI–QTOF-MS. In addition, the evolution profiles
121
of identified products during the kinetic runs were monitored by HPLC and ESI-triple
122
quadrupole mass spectrometry (HPLC/ESI−QqQ-MS) at multiple reaction monitoring
123
(MRM) mode.
124
2.3. Analytical Methods.
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126
C18 column (4.6×150 mm, 5µm particle size), a Waters 717 autosampler, and a
127
Waters 2487 dual λ detector. The mobile phase consisted of 0.1% acetic acid and
128
methanol with a ratio of 50:50 (v/v) at a flow rate of 1 mL/min. The wavelength was
129
set at 260 nm.
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An ABSciex Triple TOF X500 coupled with an AB Sciex Exion LC was used for
131
HPLC/ESI–QTOF-MS analysis. An ABSciex QTrap 5500 MS combined with an
132
Agilent 1260 HPLC was used for HPLC/ESI-QqQ-MS analysis. HPLC separation
133
was performed on a Waters XBridge C18 column (3.0 × 100 mm, 2.5 µm particle
134
size). The gradient mobile phase consisted of acetonitrile/deionized water containing
135
0.1% formic acid (A/B) at a flow rate of 0.4 mL/min, which linearly increased from
136
5% A to 95% A in the first 20 min and kept for 10 min, then went back to 5% A for
137
15 min for re-equilibration. The MS instrumental parameters were listed as follows:
138
source temperature, 500
139
arbitrary units; gas I, 50 arbitrary, gas II, 55 arbitrary units; declustering potential
140
(DP), -40 ∼ -120 V; collision energy (CE), -10 ∼-50 V; scan range (m/z), 100−800.
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C; negative ion spray voltage, -4500V; curtain gas, 35
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The DOC content of HA stock solution was determined using Analytikjena Multi
142
N/C 3100. UV–vis absorbance was measured by a Varian Cary 300 spectrometer.
143
Solution pH was measured with Leici PHS–3C pH-meter (Shanghai INESA Scientific
144
Instrument Co.Ltd). The concentration of chloride was measured by using a Dionex
145
ICS 3000 on an AS19-HC column.
146
3. Results and Discussion 7
ACCEPTED MANUSCRIPT 3.1. Reaction Kinetics
148
The time course profiles of BPS loss in the presence of excess chlorine exhibited
149
pseudo first-order kinetics over the pH range of 5-10 (see SI Figure S1a for example).
150
Moreover, the measured pseudo first-order rate constants showed a linear correlation
151
with varying chlorine concentrations (see SI Figure S1b for example). Therefore, the
152
reactions of chlorine with BPS were first-order with respect to each reactant. The
153
apparent second-order rate constants (kapp) could be accordingly determined and
154
shown in Figure 1. As can be seen, kapp exhibited a strong pH dependency. In other
155
word, kapp substantially increased from 7.6(±0.2) to 435.3(±13.1) M-1s-1 with pH
156
increasing from 5 to 8 and then decreased to 11.9(±0.4) M-1s-1 as pH further increased
157
to 10 (SI Table S2). Similar bell-shaped pH-rate profiles were also observed in
158
previous studies on the reactions of chlorine and phenolics (e.g., phenol, BPA,
159
TBrBPA, triclosan, and 4-n-nonylphenol), which were reasonably explained by the
160
combined effects of chlorine speciation and phenolic speciation as a function of pH
161
(Deborde et al. 2004, Deborde and Von Gunten 2008, Gallard and von Gunten 2002a,
162
b, Gallard et al. 2004, Lee and Von Gunten 2012, Mackie et al. 2017, Rebenne et al.
163
1996). The dissociation of phenolics (pKa1,BPS=7.42, pKa2,BPS=8.03, eqs 1-2) can result
164
in the increase of kapp as the dissociating forms exhibit stronger reactivity towards
165
chlorine (Choi and Lee 2017). The dissociation of HOCl to OCl- (pKa,HOCl = 7.54, eq 3)
166
can lead to the decrease of kapp due to the much lower reactivity of OCl- as compared
167
to HOCl (i.e., the contribution of OCl- was considered to be negligible)
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a1 ¾® BPS ¬¾¾¾ BPS- +H+ (1)
K
8
ACCEPTED MANUSCRIPT 2+ BPS- ¬¾¾¾® ¾ BPS +H (2) Ka2
169
K
a Cl ® H + +OClHOCl ¬¾ ¾¾¾ ¾
170
(3)
Recently, Lau et al. (2016) reported that Cl2 and ClO2 might take participate in
172
chlorination of phenolics (e.g., phenol and 2,4-dichloropheonol) in acid solutions (pH
173
< 6) containing high concentrations of chloride (>1mM). In addition, the involvement
174
of Cl2 and ClO2 species could result in the reaction order with respect to HOCl
175
approaching to 2. Considering the relatively low chloride concentration introduced by
176
chlorine stock solution into reaction solutions, it seemed likely that Cl2 and ClO2
177
negligibly contributed to the overall reaction. Moreover, the first-reaction-order
178
relative to HOCl in chlorination of BPS (SI Figure S1b) further precluded the
179
involvement of Cl2 and ClO2 species. Therefore, the following reactions (eqs 4-6)
180
were initially proposed to explain the pH-rate profile in chlorination of BPS.
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BPS+HOCl → product k1
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BPS- +HOCl → product k2
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k3
(6)
The apparent second-order rate constant could be expressed as follows:
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(5)
BPS2- +HOCl → product
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(4)
k app =
+
3
3
2
k1 H + + k 2 K a 1 H + + k 3 H + K a1 K a2 +
2
+
H + ( K a1 + K aCl ) H + ( K a1 K aCl + K a1 K a2 ) H + K a1 K a2 K aCl
(7)
The species-specific second-order rate constants were calculated according to
187
nonlinear least-squares regressions. The fit between experimental data and eq 7 was
188
satisfactory (Figure 1), further validating the assumption that HOCl was the primary
189
oxidant. The values of k1, k2, and k3 were calculated to be 25(± 8) M-1 s-1, (1.5 ± 0.6) ×
190
102 M-1 s-1, and (4.0 ± 0.14) × 103 M-1 s-1, respectively. A similar difference in 9
ACCEPTED MANUSCRIPT species-specific second-order rate constants (i.e., k3 >k2 >k1 ) was also observed in
192
chlorination of BPA (Gallard et al. 2004). These findings could be attributed to the
193
much higher activating effect of hydroxyl groups after their deprotonation (i.e., the
194
dissociated forms exhibited higher reactivity towards HOCl) (Deborde et al. 2004,
195
Gallard et al. 2004, Gao et al. 2016).
196
3.2. Quantitative Structure–Activity Relationship
197
In previous work, Lee and Von Gunten (2012) established a quantitative
198
structure–activity relationship (QSAR) for the species-specific rate constants of HOCl
199
and phenolate ions (e.g., dissociated forms of chlorophenols, bromophenols, triclosan,
∑σ
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−
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and 4-n-nonylphenol), where
201
among Hammett σ constants (i.e., σ, σ+, and σ-) (eq 8).
was the best substituent descriptor variable
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o ,m , p
log k H O C l = 4.46 ( ± 0.15 ) − 4.90 ( ± 0.44 ) ∑ σ
− o ,m , p
(8)
The phenolics used to obtain the QSAR (eq 8) almost all undergo chlorine
204
electrophilic substitution, as demonstrated in many studies on chlorinated products of
205
these phenolic compounds (Deborde and Von Gunten 2008, Hu et al. 2002, Lee and
206
Morris 1962, Rule et al. 2005). Due to the complex structure of BPS, the Hammett
207
constants for BPS substituents were unavailable in literature. So, a structural
208
approximation was used to estimate the Hammett substituent constants (SI Table S1).
209
This is based on the principle that the inductive/resonance effects of atoms in
210
substituents are weakened with increasing distance of the atoms from a reaction center.
211
In previous work, this structural approximation has been well applied to estimate the
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213
17a-ethinylestradiol) and their rate constants could be predicted from the developed
214
QSARs by using the estimated Hammett constants (Lee and Von Gunten 2012). In the
215
case of BPA, the substituent of 4-C(CH3)2-C6H4OH was approximated to be
216
4-C(CH3)2-CH3 and thus the structure of BPA was approximated to be
217
4-isopropylphenol (Lee and Von Gunten 2012). Similar to the case of BPA, the
218
structure of BPS was approximated to be 4-(methylsulfonyl)phenol (SI Table S1).
219
Accordingly, the species-specific rate constants of fully-dissociated BPA and BPS
220
could be predicted by eq 8 from their Hammett σ- constants (-0.13 for BPA and 1.13
221
for BPS) (Lee and Von Gunten 2012). Lee and von Gunten (2012) reported that the
222
species-specific rate constant of fully-dissociated BPA could be also well predicted by
223
the QSAR (eq 8). This was consistent with two independent studies, where BPA was
224
transformed by chlorine via electrophilic substitution pathway as confirmed by the
225
formation of chlorinated BPA (Gallard et al. 2004, Hu et al. 2002). However,
226
according to eq 8, the value of k3 for BPS was predicted to be in the range of
227
0.019-0.37 M-1 s-1, at least four orders of magnitude lower than the experimental one
228
(4.0 ± 0.14) × 103 M-1 s-1. A similar result was also obtained in a recent study on
229
chlorination of TBrBPA, and the underestimation was explained by that TBrBPA was
230
transformed by chlorine via electron transfer rather than electrophilic substitution as
231
confirmed by product analysis (Gao et al. 2016). So, it seemed likely that oxidative
232
pathway might be also involved in chlorination of BPS leading to the underestimation
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234
structure (see the following section).
235
3.3. Identification of Transformation Products
236
Figure 2 showed the HPLC/ESI-QTOF-MS chromatogram of a sample containing
237
BPS treated by chlorine at pH 7. As can be seen, six new peaks appeared as compared
238
to the control one. Product I eluting at 19.31 min had a molecular ion of 282.983. On
239
the basis of its accurate mass and isotopic pattern (SI Figure S2), the molecular
240
formula of product I was assigned as C12H8SO4Cl (i.e., [C12H9SO4Cl-H]-). It was
241
further proposed to be mono-chloro BPS in accordance with its major fragments ions
242
of 18 (H2O), 36 (HCl), 126 (C6H3ClO) and 157(C6H5SO3) (SI Figure S3). Products II
243
and III eluting at 20.46 and 20.71 min had the same molecular ion of 316.944,
244
indicating they were structural isomers. Their molecular ions displayed isotopic
245
patterns identical to the molecular formula of C12H7SO4Cl2 (i.e., [C12H8SO4Cl2-H]-)
246
(SI Figure S4). The fragment ions of product II in the product ion spectra apparently
247
included m/z 36 (HCl), 157 (C6H5SO3,) 160 (C6H2Cl2O) (SI Figure S5). So, product II
248
was supposed to be 2,6-dichloro-BPS. Product III was suggested to be
249
2,6’-dichloro-BPS in accordance with its fragment ions of 36 (HCl), 126 (C6H3ClO),
250
and 191 (C6H4SO3Cl) (SI Figure S6). Product IV at 21.12 min had a molecular ion of
251
126.996 corresponding to molecular formula of C6H4OCl (i.e., [C6H5OCl-H]-) (SI
252
Figure S7). It was further assigned to be 4-chlorophenol (4CP) according to its
253
fragment ions of 36 (HCl) and 91 (C6H3O), which was confirmed by its analytical
254
standard (SI Figure S8). Product V at 21.80 min had a molecular ion of 350.905,
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ACCEPTED MANUSCRIPT corresponding to molecular formula of C12H6SO4Cl3 (i.e., [C12H7SO4Cl3-H]-) (SI
256
Figure S9). It was further supposed to be trichloro-BPS on the basis of fragment ions
257
of 36 (HCl), 126(C6H3ClO), 160 (C6H2Cl2O), and 191 (C6H4SO3Cl) (SI Figure S10).
258
Product VI eluting at 23.05 min had a molecular ion of 384.866, exhibiting isotopic
259
patterns identical to the molecular formula of C12H5SO4Cl4 (i.e., [C12H6SO4Cl4-H]-)
260
(SI Figure S11). It was further assigned to be tetrachloro-BPS in accordance with its
261
fragment ions of 36 (HCl), 160 (C6H2Cl2O), and 225 (C6H2SO3Cl) (SI Figure S12).
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It should be noted that not all transformation products could be detected as
263
chromatographic peak by visual inspection against the baseline of the chromatogram
264
because of their different abundances and response values (Baena-Nogueras et al.
265
2017, Gulde et al. 2016). Therefore, the Analytics software (AB Sciex) was further
266
applied to pick up possible products through suspect analysis on the basis of accurate
267
mass measurement, specific fragments, as well as comparison of theoretical and
268
measured isotopic patterns. As a consequence, additional five products (VII-XI) were
269
identified. Products VII and VIII were isomeric dimers of BPS. Product IX was
270
assigned to be 4-hydroxybenzenesulfonic acid (BSA), which was further confirmed
271
by its analytical standards. Products X and XI were proposed to be mono- and
272
dichloro-BSA, respectively. In order to confirm this, transformation products of BSA
273
treated by chlorine were detected and the chromatogram was shown in SI Figure S13,
274
where products X and XI were obvious. In summary, a total of eleven products were
275
identified in chlorination of BPS and their detailed information including retention
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277
in Table 1.
278
3.4. Proposed Reaction Pathways
279
On the basis of identified products, transformation pathways for chlorination of BPS
280
were tentatively proposed as shown in Figure 3. BPS was initially attacked by
281
chlorine substitution with the formation of monochloro-BPS (product I), which
282
subsequently underwent stepwise substitution reactions leading to the generation of
283
di/tri/tetrachloro-BPS (products II, III, V, and VI). Similar chlorine electrophilic
284
substitution was also reported in chlorination of BPA (Gallard et al. 2004). This
285
transformation pathway (pathway i) is consistent with the fact that electrophilic
286
substitution is a main chlorination pathway for aromatic rings (Deborde and Von
287
Gunten 2008, Gallard et al. 2004, Lee and Morris 1962). In addition, an oxidative
288
pathway (pathway ii) was proposed to account for the formation of 4CP (product VI),
289
dimers (prdocuts VII and VIII) and BSA (product IX): the phenol moiety of BPS was
290
initially oxidized by chlorine with the formation of a phenoxy radical R1. Then radical
291
R1 coupled to each other with the formation of dimers (products VII and VIII), or
292
cleavaged to release R2 radical and R3 cation. Subsequently, R2 radical was further
293
transformed to 4CP (product IV). R3 intermediate underwent substitution reactions to
294
generate BSA (product IX), which might be further attacked by chlorine substitution
295
with the generation of chlorinated BSA (product X and XI). Similar transformation
296
pathway ii was also reported in TBrBPA oxidation by chlorine (Gao et al. 2016).
297
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Kuruto-Niwa
et
al.
(2005)
reported 14
that
chlorinated
BPS
(i.e.,
ACCEPTED MANUSCRIPT mono/di/tri/tetrachloro-BPS) showed a substantially lower estrogenic activity
299
compared to BPS using a green fluorescent protein expression system, in contrast to
300
the findings that chlorinated BPA exhibited higher estrogenic activity compared to
301
parent BPA. In addition, the estrogenic activity of 4-CP was found to be very low as
302
reported by Nishihara et al. (2000). By testing the estrogenic activity of more than 500
303
chemicals, Nishihara et al. (2000) concluded that the estrogen activity of substituent
304
phenolics was positively related to their hydrophobic moiety at the para-position. So,
305
several oxidative products of BPS by chlorine (e.g., BSA and its chlorinated
306
derivatives) are expected to show an appreciably low estrogenic activity due to
307
hydrophilicity of sulfonic group. Therefore, it seems likely that chlorine treatment
308
may also eliminate estrogenic activity induced by BPS, which warrants further
309
verification by laboratory tests.
310
3.5. Effect of HA on Chlorination of BPS
311
3.5.1. Effect of HA on Reaction Kinetics.
312
Kinetic experiments were conducted to assess the effect of HA (0.5-2mgC/L) during
313
chlorination (30 µM) of BPS (1 µM) at an environmentally relevant pH 7. Figure 4
314
exhibited the time course profiles of BPS degradation and chlorine loss, respectively.
315
As can be seen, the presence of HA appreciably suppressed the degradation of BPS.
316
With the concentration of HA increasing from 0 to 2 mg C/L, the extent of BPS loss
317
greatly decreased from 86% to 46% at 15 minute. HA could competitively consume
318
oxidant thus leading to the decrease of degradation rates (Gallard et al. 2004, Yang et
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15
ACCEPTED MANUSCRIPT 319
al. 2014). In order to account for this effect, eq 9 was introduced to quantify the
320
kinetics Ct
321
C0
=exp{ -k
t 0
HOCl dt }
(9)
where Ct was the concentration of BPS at a specific time t, C0 was the initial
323
concentration of BPS, and
324
over time (i.e., chlorine exposure). It was found that the predictions made according to
325
eq 9 considerably overestimated the level of BPS loss in the presence of HA (SI
326
Figure 14). In addition, the transformation rate constants (k) at different
327
concentrations of HA could be obtained by eq 9. As shown in Figure 5, the rate
328
constants (k) decreased with the increase of HA concentration. Similar inhibition was
329
also observed in chlorination of TBrBPA, which was reasonably explained by the fact
330
that TBrBPA phenoxyl radicals formed by one-electron chlorine oxidation were
331
competitively reduced back to its parent by HA. Interestingly, it was also found that
332
HA had negligible influence on the degradation of BPA by chlorine, where the
333
reaction proceeded via chlorine electrophilic substitution (Gao et al. 2016).
334
Considering the two-channel pathways involved in chlorination of BPS, we
335
tentatively proposed that HA inhibited the degradation of BPS by chlorine via
336
electron transfer (pathway ii), similar to the case of TBrBPA. In parallel, HA had
337
negligible effect on the depletion of BPS transformed via electrophile substitution
338
(pathway i), similar to the case of BPA.
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HOCl dt was the chlorine concentration integrated
339
A two-channel kinetic model was accordingly introduced to further characterize the
340
effect of HA. Contaminants (P) was transformed by chlorine with the formation of 16
ACCEPTED MANUSCRIPT intermediate P1 (via electron transfer) with a yield r and P2 (via electrophilic
342
substitution) with a yield (1-r) (eq 10). P1 would be competitively reduced by HA to
343
its original form P (eq 11), in addition to its further irreversibly transformation (eq
344
12).
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341
P+chlorine → rP1 +(1-r)P2 (10) k4
345
P1 +HA → P (11) k5
P1 → Products k6
347
(12)
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346
The reactions 10 and 11 were both second-order to reactants, where k4 represented the
349
rate constants in the absence of HA (eq 10), and k5 was the rate constants for the
350
reaction of intermediate P1 with HA (eq 11). k6 was the first-order rate constant for eq
351
12. Therefore, kinetic equations 13 and 14 could be obtained to describe the
352
degradation rate for P and the formation rate for P1, respectively. dP dt
356 357
358
(13)
=rk4 P chlorine -k6 P1 -k5 P1 HA
(14)
By making a steady-state assumption for [P1], eq 15 could be obtained:
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d P1 dt
dP
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354
=k4 P chlorine -k5 P1 HA
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353
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dt
=k4 1-r+ k
rk6 5
P chlorine
HA +k6
(15)
Therefore, the rate constant in the presence of HA could be described as eq 16 kHA =k4 1-r+ k
rk6 5
HA +k6
= k4 1-r+ k5 k6
r HA +1
(16)
359
As can be seen in Figure 5, the two-channel kinetic model (eq 16) could fit the
360
experimental data well. The values of r and k5/k6 was estimated to 0.64(±0.02) and
361
1.66(±0.18), respectively. These results indicated that the contribution of electron
17
ACCEPTED MANUSCRIPT 362
transfer and electrophilic substitution pathway to BPS degradation was around 64%
363
and 36%, respectively.
364
3.5.2. Effect of HA on Products Formation. (i) products analysis. The effect of HA on the products formation during
366
chlorination of BPS was also investigated. No additional products were detected in the
367
presence of HA compared to the case in the absence of HA (data not shown). This
368
finding was similar to the scenario of chlorination of TBrBPA, where HA had
369
negligible impact on the products species either (Gao et al. 2016). The influence of
370
HA on products formation during oxidation processes (e.g., permanganate, ferrate,
371
and enzymatic catalysis) was also investigated in previous work but confounding
372
effects were reported (Gao et al. 2016, Li et al. 2017, Lu et al. 2015, Lu and Huang
373
2009, Lu et al. 2017). For instance, Li et al. (2017) reported that HA negligibly
374
influenced the products species in soybean-catalyzed oxidation of triclosan. On the
375
contrary, Feng et al. (2013) reported that HA affected the products species in
376
laccase-catalyzed oxidation of TBrBPA, where additional new products with large
377
molecular ions were detected in the presence of HA. It seemed likely that the effect of
378
HA on the products species was complex, which might be associated with the nature
379
of HA and the experimental conditions.
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365
Due to the complexity of HA molecular structure, model compounds with defined
381
structures were used to further explore the effect of HA. In previous work,
382
2-methoxyphenol was commonly used to mimic HA (Li et al. 2017, Lu and Huang
383
2009, Lu et al. 2017). For instance, Lu and Huang (2009) reported that the presence of 18
ACCEPTED MANUSCRIPT 2-methoxyphenol in laccase-catalysis oxidation of acetaminophen led to the formation
385
of a new product, resulting from the coupling of 2-methoxyphenol and
386
acetamionphenol phenoxy radicals. Similarly, cross-coupling products were also
387
detected in soybean peroxidase-catalysis oxidation of triclosan. In this work, a new
388
product with a molecular ion of 371.059 was detected when 2-methoxyphenol was
389
present during chlorination of BPS. This new product was likely generated from cross
390
coupling of BPS and 2-methoxyphenol phenoxy radicals (SI Figure 15). This finding
391
in turn confirmed the occurrence of oxidative pathway during chlorination of BPS.
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384
Interestingly, several studies reported that co-solvent methanol could affect the
393
product species during BPA or TBrBPA oxidation (e.g., by permanganate, ferrate,
394
manganese dioxide or enzymatic catalysis oxidation), which was also verified in this
395
work (SI Table S3) (Feng et al. 2013, Gao et al. 2016, Yang et al. 2014). Carbocation
396
intermediates of 4-isopropylphenol or 2,6-dibromo-4-isopropylphenol formed during
397
BPA or TBrBPA oxidation, underwent substitution reactions with methanol (other
398
than
399
2,6-dibromo-hydroxy-isopropyl methanol (SI Table S3). Similarly, a new product
400
with a molecular ion of 187.007 was detected in chlorination of BPS when methanol
401
was present. This new product was suggested
402
benzenesulfonate (SI Figure 16), which was derived from the substitution reaction of
403
methanol and R3 intermediate. This finding confirmed again the occurrence of
404
oxidative pathway during chlorination of BPS.
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392
to
generate
4-hydroxy-isopropyl
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water)
19
methanol
or
to be 4-hydroxy-methyl
ACCEPTED MANUSCRIPT (ii) products evolution. The time course profiles of transformation products of BPS
406
by chlorine in the absence vs presence of HA were comparatively monitored by the
407
HPLC/ESI-QqQ-MS at MRM mode (Figure 6). In the absence of HA, the
408
consecutive formation of chlorinated BPS (generated through chlorine electrophilic
409
substitution pathway) was followed by their decay as a function of time, where
410
mono/di/tri/tetrachloro-BPS reached their maxima at about 5, 8, 15, and 35 min,
411
respectively. As the reaction proceeded, tetrachloro-BPS became the only chlorinated
412
BPS congeners. 4CP (generated via electron transfer pathway) was gradually
413
accumulated within 15 min and then declined. The maximum yield of 4CP was
414
quantified by the authentic standard to be about ~2% with respect to BPS loss.
415
Unfortunately, the response values of BSA and polymeric products (also generated
416
via electron transfer pathway) were too low and thus the formation dynamics of BSA
417
and its chlorinated products as well as the two dimers were not followed.
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405
In the presence of HA, the formation of monochloro-BPS was also followed by its
419
decay along with the reaction time but the occurrence of its maxima was prolonged to
420
about 25 min. Dichloro-BPS and trichloro-BPS were gradually generated and then
421
reached plateaus, while tetrachloro-BPS was negligibly generated. In particular, the
422
maximum yield of monochloro-BPS was calculated to be ~0.53 by using peak areas
423
(i.e., dividing its peak area by the decreased peak area of BPS) due to the lack of
424
authentic standard, which was higher than that obtained in the absence of HA (~0.40).
425
Along with reaction time, 4CP slowly accumulated to a plateau and its maximum
426
yield was calculated to be about ~1.1%, lower than that obtained in the absence of HA
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418
20
ACCEPTED MANUSCRIPT (~2%). These findings that HA increased the yield of monochloro-BPS and decreased
428
the yield of 4CP were in consistent with the conclusion deduced from the two-channel
429
model, where BPS was transformed by two parallel pathways and HA could inhibit
430
the degradation of BPS via electron transfer pathway.
431
4. Conclusion
432
This work firstly investigated the transformation of BPS by chlorine including
433
kinetics, products, mechanism, and the effect of HA. The following conclusions were
434
obtained, which might improve the understanding of chlorine chemistry in water
435
treatment:
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Chlorine could effectively degrade BPS over a wide pH range from 5-10 with the
437
apparent second-order rate constants of 7.6-435.3 M−1s−1.With a typical chlorine
438
residual concentration of 2 mg/L, the half life time of BPS was calculated to be
439
around 0.94-3.2 min at pH 7-8.
440
Eleven products including chlorinated BPS (i.e., mono/di/tri/tetrachloro-BPS),
441
4CP, BSA, chlorinated BSA (i.e., mono/dichloro-BSA) and two dimers were
442
detected by HPLC/ESI–QTOF-MS. It was proposed that BPS was transformed by
444 445
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436
chorine via two parallel pathways including chlorine electrophile substitution and electron transfer pathways. The inhibitory effect of HA on BPS degradation was reasonably explained by a
446
two-channel kinetic model, where HA negligibly influenced electrophile
447
substitution while appreciably inhibited the degradation of BPS through electron
448
transfer via reversing BPS phenoxyl radical back to parent BPS. 21
ACCEPTED MANUSCRIPT HA had negligible impact on the product species in chlorination of BPS.
450
However, in the presence of 2-methoxyphenol, a new additional product was
451
generated via cross coupling of BPS and 2-methoxyphenol phenoxy radicals. In
452
the case of co-solvent methanol, 4-hydroxy-methyl benzenesulfonate derived
453
from the substitution reaction of methanol and an intermediate was generated.
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449
Acknowledgments
455
This work was supported by the National Natural Science Foundation of China
456
(51578203); the Funds of the State Key Laboratory of Urban Water Resource and
457
Environment (HIT, 2016DX13); and the Foundation for the Author of National
458
Excellent Doctoral Dissertation of China (201346).
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ACCEPTED MANUSCRIPT 460
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26
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Table1. Products of BPS transformed by chlorine Found at mass
Formular
BPS
17.77
249.0224
C12H10SO4
20.71
316.9444
C12H9SO4Cl
C12H8SO4Cl2
316.9445
C12H8SO4Cl2
21.12
AC C
IV
126.9957
Proposed structural
-1.2
O S O
HO
-0.9
O S
OH
O
-1.0
Cl 2
HO
3
1
4
6
5
O S O
3'
2'
4'
1'
5'
OH
6'
Cl
-0.8
Cl 2
HO
1.0
3
1
4
6
C6H5OCl
OH
Cl HO
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III
20.46
282.9835
M AN U
II
19.31
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I
Mass Error(ppm)
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Retention time
SC
Product number
HO
5
O S O
3'
2'
4'
1'
5'
6'
Cl
Cl
OH
ACCEPTED MANUSCRIPT
VII
18.76
20.08
497.0363
SC
384.8666
C12H7SO4Cl3
C12H6SO4Cl4
C24H18S2O4
497.0366
C24H18S2O8
-0.7
Cl
Cl O S O
HO
7.81
AC C
IX
172.9915
OH Cl
-0.5
Cl
Cl O HO
S O
OH
Cl
-1.4
Cl
O S O
HO
OH HO
O S
OH
O
-0.8
O S O
HO
EP
VIII
23.05
350.9055
M AN U
VI
21.80
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V
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Table1(continuted)
OH O
O S O
OH
C6H6SO8
0.5
O HO S O
OH
ACCEPTED MANUSCRIPT
Table1(continuted)
-0.6
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C6H4SO4Cl2
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C6H5SO4Cl
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16.46
206.9523
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XI
13.60
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X
-1.4
O HO S O O HO S O
Cl OH
Cl OH Cl
ACCEPTED MANUSCRIPT
500
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300
-1 -1
kapp(M s )
400
SC
200
0 5
6
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100
7
8
9
10
pH
Figure 1. pH dependency of apparent second-order rate constants for the reactions of
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the model fit by eq 7.
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chlorine with BPS. Symbols represent measured data and the dashed line represents
ACCEPTED MANUSCRIPT
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BPS
2
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1
6
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﹡
﹡
﹡
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3 4
Figure 2. The HPLC/ESI–QTOF-MS chromatogram of a sample containing BPS treated by chlorine. Asterisks represent the impurities.
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Experimental condition: [BPS] = 10 µM, [chlorine] = 30 µM, and pH 7.
ACCEPTED MANUSCRIPT
Cl O S O
OH
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HO Cl
II
Cl
chlorine
OH
HO
Cl
I
O HO
S O
OH
Cl
Cl OH
O S O
HO
Cl
OH
Cl
Cl
VI
V
Cl
OH
III
O
BPS
chlorine HO
O S
HO
O
O
R1
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HO
H2O
S O
HO
O S O
O S O
O
O S OH O
HO
R3
HO
Cl
IV
R2
O
Electron transfer
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HO
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HO
O S
Cl
O S O
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HO
Cl
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O S O
HO
O S OCH3 O
HO
O S O
self-coupling
O
HO
VII
or
OH O S O
Cl
O HO S O
OH
X
IX CH3OH
Cl
O HO S O
OH Cl
XI
HO
OH
O S O
O
O S O
OH
VIII
OH
ACCEPTED MANUSCRIPT
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Figure 3. The proposed pathway for the reaction of chlorine with BPS.
[chlorine]t/[chlorine]0
0.8 0.6
HA=0mgC/L HA=0.5mgC/L HA=1mgC/L HA=2mgC/L
0.2 0.0
0
5
0.8 0.6
0.2 0.0
10
Time(min)
15
(b)
0.4
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(a)
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0
HA=0mgC/L HA=0.5mgC/L HA=1mgC/L HA=2mgC/L
5
10
15
Time(min)
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1 µM, [chlorine] = 30 µM, and pH 7.
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Figure 4. The time course profiles of BPS degradation (a) and chlorine loss (b) at different HA concentrations. Experimental condition: [BPS]=
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90
-1
k(M s-1)
120
30 0.0
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60
0.5
1.0
2
R =0.99
1.5
2.0
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HA (mgC/L)
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Figure 5. HA concentration dependency of measured second-order rate constants for the reaction of chlorine (30 µM) with BPS (1 µM) at pH 7. Symbols represent measured data and the dashed line represents the model fit by eq 16.
0
0 0
25
50
75
100
3
1
0
0
25
-2
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2
20000
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Time (min)
product I product II product III product IV product V
concentration (×10 µΜ)
1 20000
40000
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60000
-2
2
80000
Area
Area
60000
(b)
3
concentration (×10 µΜ)
product I product II product III product IV product V product VI
(a)
80000
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0 50
75
100
Time (min)
Figure 6. The evolution profiles of identified products of BPS by the treatment of chlorine in the absence (a) and presence of HA (b).
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Experimental condition: [BPS]= 1 µM, [chlorine] = 30 µM, [HA] = 2 mgC/L, and pH 7
ACCEPTED MANUSCRIPT Highlights: BPS could be effectively degraded by chlorine over pH of 5-10 (kapp 7.6-435.3 M−1s−1) A total of eleven products were detected by HPLC/ESI-QTOF-MS
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Two parallel pathways (electrophilic substitution & electron transfer) were proposed Inhibitory effect of HA on degradation was explained by a two-channel kinetic model
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HA had negligible effect on product species in chlorination of BPS
S0043-1354(17)31044-8
DOI:
10.1016/j.watres.2017.12.049
Reference:
WR 13447
To appear in:
Water Research
Received Date: 9 September 2017 Revised Date:
18 December 2017
Accepted Date: 19 December 2017
Please cite this article as: Gao, Y., Jiang, J., Zhou, Y., Pang, S.-Y., Ma, J., Jiang, C., Yang, Y., Huang, Z.-s., Gu, J., Guo, Q., Duan, J.-B., Li, J., Chlorination of bisphenol S: Kinetics, products, and effect of humic acid, Water Research (2018), doi: 10.1016/j.watres.2017.12.049. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. 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.
ACCEPTED MANUSCRIPT 1
Chlorination of Bisphenol S: Kinetics, Products, and
2
Effect of Humic Acid
3
Yuan Gaoa, Jin Jianga,*, Yang Zhoua, Su-Yan Pangb,*, Jun Maa, Chengchun Jiangc,
5
Yue Yangd, Zhuang-song Huanga, Jia Gua, Qin Guod, Jie-Bin Duand, and Juan Lia
6
a
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Municipal and Environmental Engineering, Harbin Institute of Technology, Harbin
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150090, China
9
b
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State Key Laboratory of Urban Water Resource and Environment, School of
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School of Municipal and Environmental Engineering, Jilin Jianzhu University,
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Changchun 130118, China
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c
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518055, China
13
d
14
and Technology, Harbin 150040, China
15
*Corresponding Author: Prof. Jin Jiang, E-mail: [email protected];
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*Corresponding Author: Prof. Su-Yan Pang, E-mail: [email protected]
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College of Chemical and Environmental Engineering, Harbin University of Science
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School of Civil and Environmental Engineering, Shenzhen Polytechnic, Shenzhen
1
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Abstract
19
Bisphenol S (BPS), as a main alternative of bisphenol A for the production of
20
industrial and consumer products, is now frequently detected in aquatic environments.
21
In this work, it was found that free chlorine could effectively degrade BPS over a
22
wide pH range from 5-10 with apparent second-order rate constants of 7.6-435.3
23
M−1s−1.
24
mono/di/tri/tetrachloro-BPS), 4-hydroxybenzenesulfonic acid (BSA), chlorinated
25
BSA (mono/dichloro-BSA), 4-chlorophenol (4CP), and two polymeric products were
26
detected
27
ionization-tandem quadrupole time-of-flight mass spectrometry. Two parallel
28
transformation pathways were tentatively proposed: (i) BPS was attacked by stepwise
29
chlorine electrophilic substitution with the formation of chlorinated BPS. (ii) BPS was
30
oxidized by chlorine via electron transfer leading to the formation of BSA, 4CP and
31
polymeric products. Humic acid (HA) significantly suppressed the degradation rates
32
of BPS even taking chlorine consumption into account, while negligibly affected the
33
products species. The inhibitory effect of HA was reasonably explained by a
34
two-channel kinetic model. It was proposed that HA negligibly influenced pathway i
35
while appreciably inhibited the degradation of BPS through pathway ii, where HA
36
reversed BPS phenoxyl radical (formed via pathway ii) back to parent BPS.
37
Keywords: Bisphenol S; Chlorine; Humic acid; Electrophilic substitution; Electron
38
transfer
total
of
eleven
products
including
chlorinated
BPS
(i.e.,
high
performance
liquid
chromatography
and
electrospray
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2
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1. Introduction
40
Due to the widespread occurrence of bisphenol A (BPA) and its adverse effect on
41
both human and ecosystem health, organizations such as the United States
42
Environmental Protection Agency (USEPA) and the European Food Safety Authority
43
(EFSA) established a limit to BPA (Barroso 2011, Staples et al. 1998, Vandenberg et
44
al. 2007). In response to these restrictions and public pressure, bisphenol S (BPS;
45
4,4’-sulfonyldiphenol) is gradually used in replacement of BPA. BPS is commonly
46
used in epoxy glues, canned coatings, foodstuffs, and paper products (Naderi et al.
47
2014). Therefore, the occurrence of BPS in the aquatic environments has been
48
documented in recent years (Liao et al. 2012, van Leerdam et al. 2014, Yamazaki et
49
al. 2015, Yang et al. 2014). For instance, Yamazaki et al. (2015) reported the
50
occurrence of BPS as high as 6840 ng/L in surface water and seawater of Japan,
51
China, Korea and India. Liao et al. (2012) reported that BPS was present in the
52
sediment of United States, Japan, and Korea up to the concentration of 1970 ng/g dry
53
weight. Unfortunately, several studies have reported that BPS has similar estrogenic
54
activity and appears to be more resistant to environmental degradation as compared to
55
BPA (Danzl et al. 2009, Hashimoto et al. 2001, Rochester and Bolden 2015).
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Chlorine is a globally most used chemical for water disinfection. In addition, it
57
has been well documented that chlorine can react with a wide range of organic
58
contaminants especially phenolic compounds (Deborde et al. 2004, Deborde and Von
59
Gunten 2008, Dodd et al. 2005, Dodd and Huang 2007, Gallard and von Gunten
60
2002a, b, Gallard et al. 2004, Gao et al. 2016, Rebenne et al. 1996). For instance, 3
ACCEPTED MANUSCRIPT Gallard et al. (2004) reported that BPA could be appreciably degraded by chlorine
62
with a second-order rate constant of 58 M-1 s-1 at pH 7.0 (at 20 oC), where
63
chlorinated-BPA was generated via stepwise electrophilic substitution. In a very
64
recent work, we found that chlorine could rapidly oxidize tetrabromobisphenol A
65
(TBrBPA) via electron transfer with a second-order rate constant of 1360 M−1 s−1 at
66
pH 7.0 (at 25 oC), where oxidative product 2,6-dibromo-4-hydroxycumyl alcohol was
67
predominantly generated (Gao et al. 2016, Lin et al. 2009a, Yang et al. 2014).
68
However, the reactions of chlorine with BPS, structurally similar to BPA and
69
TBrBPA (see Table S1 for their chemical structures), have not been characterized so
70
far.
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Dissolved organic matter (DOM), ubiquitously existing in diverse aquatic
72
environments, may exert important impacts on the transformation of contaminants in
73
natural environments and engineered processes. As a competitor for oxidant, DOM
74
can suppress the degradation of contaminants in numerous chemical oxidation
75
processes (Fang et al. 2014, Gallard et al. 2004, Li et al. 2017, Lu et al. 2015, Luo et
76
al. 2016, Sharma et al. 2015). Another inhibitory effect of DOM has been reported to
77
take place in excited triplet states, permanganate, ferrate or enzymatic catalysis
78
oxidation (Canonica and Laubscher 2008, Feng et al. 2013, Gao et al. 2016, Leresche
79
et al. 2016, Lu et al. 2015, Vione et al. 2017, Wenk et al. 2011, Wenk et al. 2015),
80
where DOM can reduce the reactive intermediates formed via one electron-transfer
81
back to parent contaminants. Interestingly, in our recent work, this inhibitory effect of
82
DOM was also observed in chlorination of TBrBPA while not in chlorination of BPA
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4
ACCEPTED MANUSCRIPT 83
(Gao et al. 2016). The contrasting effects might be related to the distinct pathways
84
involved in chlorination of BPA vs TBrBPA (i.e., electrophilic substitution for BPA
85
vs electron transfer for TBrBPA) (Gao et al. 2016). In this work, the transformation kinetics and products of BPS by chlorine as well
87
as the effect of HA were investigated for the first time. Firstly, reaction kinetics were
88
studied in synthetic buffered waters over pH range of 5-10. Secondly, transformation
89
products of BPS by chlorine were identified by a high performance liquid
90
chromatography and electrospray ionization-tandem quadrupole time-of-flight mass
91
spectrometry (HPLC/ESI-QTOF-MS), and the tentative pathways were proposed.
92
Finally, the effects of HA on the transformation of BPS by chlorine were investigated.
93
2. Experimental Section
94
2.1. Materials.
95
BPS,
96
2,2-azino-bis(3-ethylbenzothiazoline)-6-sulfonic acid diammonium (ABTS) were
97
purchased from Sigma-Aldrich. Sodium hypochlorite and sodium thiosulfate were
98
purchased from Sinopharm Chemical Reagent Co. Ltd., China. All reagents used were
99
of 97% purity or higher without further purification unless otherwise stated. Solutions
100
were prepared in deionized water (18.2 MΩcm) from a Milli-pore system. The stock
101
solutions of chlorine were prepared by diluting a commercial solution of sodium
102
hypochlorite (NaClO, 4% active chlorine) and standardized by iodometry. The stock
103
solutions of HA were purified by repeated pH adjustment, filtration and precipitation
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acid
(HA;
surrogate
of
DOM),
2-methoxyphenol,
and
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humic
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5
ACCEPTED MANUSCRIPT 104
following the procedure described in our previous work and its concentration was
105
measured in mgC/L (Gao et al. 2016, Rebhun et al. 1998).
106
2.2. Experimental procedure. Kinetic studies were performed in 50 mL conical flasks under constant stirring at
108
25(±2) oC. Reactions were initiated by adding chlorine in excess (10-400 µM) into
109
pH-buffered solutions (10 mM phosphate buffer for pH 5-10) containing BPS (1 µM)
110
with/without HA (0.5-2 mgC/L). At a specific time interval, two parallel samples
111
were withdrawn, and one was quenched by thiosulfate to measure residual BPS and
112
the other was quenched by ABTS to measure residual chlorine (Pinkernell et al. 2000,
113
Song et al. 2015). The changes of solution pH were negligible (< 0.1) during the
114
kinetic runs. All the kinetic experiments were performed in triplicates and average
115
data were presented. The relative standard deviations were always <10% unless
116
otherwise stated.
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For products identification, a series of pH-buffered (pH 7) solutions containing
118
BPS (at a relatively high concentration of 10 µM) with/without HA (0.5-5 mg C/L)
119
were prepared and treated by chlorine at various doses (5-50 µM). The resulting
120
solutions were analyzed by HPLC/ESI–QTOF-MS. In addition, the evolution profiles
121
of identified products during the kinetic runs were monitored by HPLC and ESI-triple
122
quadrupole mass spectrometry (HPLC/ESI−QqQ-MS) at multiple reaction monitoring
123
(MRM) mode.
124
2.3. Analytical Methods.
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6
ACCEPTED MANUSCRIPT BPS was determined using a Waters 1525 HPLC equipped with a Waters symmetry
126
C18 column (4.6×150 mm, 5µm particle size), a Waters 717 autosampler, and a
127
Waters 2487 dual λ detector. The mobile phase consisted of 0.1% acetic acid and
128
methanol with a ratio of 50:50 (v/v) at a flow rate of 1 mL/min. The wavelength was
129
set at 260 nm.
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An ABSciex Triple TOF X500 coupled with an AB Sciex Exion LC was used for
131
HPLC/ESI–QTOF-MS analysis. An ABSciex QTrap 5500 MS combined with an
132
Agilent 1260 HPLC was used for HPLC/ESI-QqQ-MS analysis. HPLC separation
133
was performed on a Waters XBridge C18 column (3.0 × 100 mm, 2.5 µm particle
134
size). The gradient mobile phase consisted of acetonitrile/deionized water containing
135
0.1% formic acid (A/B) at a flow rate of 0.4 mL/min, which linearly increased from
136
5% A to 95% A in the first 20 min and kept for 10 min, then went back to 5% A for
137
15 min for re-equilibration. The MS instrumental parameters were listed as follows:
138
source temperature, 500
139
arbitrary units; gas I, 50 arbitrary, gas II, 55 arbitrary units; declustering potential
140
(DP), -40 ∼ -120 V; collision energy (CE), -10 ∼-50 V; scan range (m/z), 100−800.
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C; negative ion spray voltage, -4500V; curtain gas, 35
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o
141
The DOC content of HA stock solution was determined using Analytikjena Multi
142
N/C 3100. UV–vis absorbance was measured by a Varian Cary 300 spectrometer.
143
Solution pH was measured with Leici PHS–3C pH-meter (Shanghai INESA Scientific
144
Instrument Co.Ltd). The concentration of chloride was measured by using a Dionex
145
ICS 3000 on an AS19-HC column.
146
3. Results and Discussion 7
ACCEPTED MANUSCRIPT 3.1. Reaction Kinetics
148
The time course profiles of BPS loss in the presence of excess chlorine exhibited
149
pseudo first-order kinetics over the pH range of 5-10 (see SI Figure S1a for example).
150
Moreover, the measured pseudo first-order rate constants showed a linear correlation
151
with varying chlorine concentrations (see SI Figure S1b for example). Therefore, the
152
reactions of chlorine with BPS were first-order with respect to each reactant. The
153
apparent second-order rate constants (kapp) could be accordingly determined and
154
shown in Figure 1. As can be seen, kapp exhibited a strong pH dependency. In other
155
word, kapp substantially increased from 7.6(±0.2) to 435.3(±13.1) M-1s-1 with pH
156
increasing from 5 to 8 and then decreased to 11.9(±0.4) M-1s-1 as pH further increased
157
to 10 (SI Table S2). Similar bell-shaped pH-rate profiles were also observed in
158
previous studies on the reactions of chlorine and phenolics (e.g., phenol, BPA,
159
TBrBPA, triclosan, and 4-n-nonylphenol), which were reasonably explained by the
160
combined effects of chlorine speciation and phenolic speciation as a function of pH
161
(Deborde et al. 2004, Deborde and Von Gunten 2008, Gallard and von Gunten 2002a,
162
b, Gallard et al. 2004, Lee and Von Gunten 2012, Mackie et al. 2017, Rebenne et al.
163
1996). The dissociation of phenolics (pKa1,BPS=7.42, pKa2,BPS=8.03, eqs 1-2) can result
164
in the increase of kapp as the dissociating forms exhibit stronger reactivity towards
165
chlorine (Choi and Lee 2017). The dissociation of HOCl to OCl- (pKa,HOCl = 7.54, eq 3)
166
can lead to the decrease of kapp due to the much lower reactivity of OCl- as compared
167
to HOCl (i.e., the contribution of OCl- was considered to be negligible)
168
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a1 ¾® BPS ¬¾¾¾ BPS- +H+ (1)
K
8
ACCEPTED MANUSCRIPT 2+ BPS- ¬¾¾¾® ¾ BPS +H (2) Ka2
169
K
a Cl ® H + +OClHOCl ¬¾ ¾¾¾ ¾
170
(3)
Recently, Lau et al. (2016) reported that Cl2 and ClO2 might take participate in
172
chlorination of phenolics (e.g., phenol and 2,4-dichloropheonol) in acid solutions (pH
173
< 6) containing high concentrations of chloride (>1mM). In addition, the involvement
174
of Cl2 and ClO2 species could result in the reaction order with respect to HOCl
175
approaching to 2. Considering the relatively low chloride concentration introduced by
176
chlorine stock solution into reaction solutions, it seemed likely that Cl2 and ClO2
177
negligibly contributed to the overall reaction. Moreover, the first-reaction-order
178
relative to HOCl in chlorination of BPS (SI Figure S1b) further precluded the
179
involvement of Cl2 and ClO2 species. Therefore, the following reactions (eqs 4-6)
180
were initially proposed to explain the pH-rate profile in chlorination of BPS.
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BPS+HOCl → product k1
181
BPS- +HOCl → product k2
182
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k3
(6)
The apparent second-order rate constant could be expressed as follows:
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(5)
BPS2- +HOCl → product
183 184
(4)
k app =
+
3
3
2
k1 H + + k 2 K a 1 H + + k 3 H + K a1 K a2 +
2
+
H + ( K a1 + K aCl ) H + ( K a1 K aCl + K a1 K a2 ) H + K a1 K a2 K aCl
(7)
The species-specific second-order rate constants were calculated according to
187
nonlinear least-squares regressions. The fit between experimental data and eq 7 was
188
satisfactory (Figure 1), further validating the assumption that HOCl was the primary
189
oxidant. The values of k1, k2, and k3 were calculated to be 25(± 8) M-1 s-1, (1.5 ± 0.6) ×
190
102 M-1 s-1, and (4.0 ± 0.14) × 103 M-1 s-1, respectively. A similar difference in 9
ACCEPTED MANUSCRIPT species-specific second-order rate constants (i.e., k3 >k2 >k1 ) was also observed in
192
chlorination of BPA (Gallard et al. 2004). These findings could be attributed to the
193
much higher activating effect of hydroxyl groups after their deprotonation (i.e., the
194
dissociated forms exhibited higher reactivity towards HOCl) (Deborde et al. 2004,
195
Gallard et al. 2004, Gao et al. 2016).
196
3.2. Quantitative Structure–Activity Relationship
197
In previous work, Lee and Von Gunten (2012) established a quantitative
198
structure–activity relationship (QSAR) for the species-specific rate constants of HOCl
199
and phenolate ions (e.g., dissociated forms of chlorophenols, bromophenols, triclosan,
∑σ
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−
200
and 4-n-nonylphenol), where
201
among Hammett σ constants (i.e., σ, σ+, and σ-) (eq 8).
was the best substituent descriptor variable
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o ,m , p
log k H O C l = 4.46 ( ± 0.15 ) − 4.90 ( ± 0.44 ) ∑ σ
− o ,m , p
(8)
The phenolics used to obtain the QSAR (eq 8) almost all undergo chlorine
204
electrophilic substitution, as demonstrated in many studies on chlorinated products of
205
these phenolic compounds (Deborde and Von Gunten 2008, Hu et al. 2002, Lee and
206
Morris 1962, Rule et al. 2005). Due to the complex structure of BPS, the Hammett
207
constants for BPS substituents were unavailable in literature. So, a structural
208
approximation was used to estimate the Hammett substituent constants (SI Table S1).
209
This is based on the principle that the inductive/resonance effects of atoms in
210
substituents are weakened with increasing distance of the atoms from a reaction center.
211
In previous work, this structural approximation has been well applied to estimate the
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10
ACCEPTED MANUSCRIPT Hammett σ constants for structurally complex compounds (e.g., BPA and
213
17a-ethinylestradiol) and their rate constants could be predicted from the developed
214
QSARs by using the estimated Hammett constants (Lee and Von Gunten 2012). In the
215
case of BPA, the substituent of 4-C(CH3)2-C6H4OH was approximated to be
216
4-C(CH3)2-CH3 and thus the structure of BPA was approximated to be
217
4-isopropylphenol (Lee and Von Gunten 2012). Similar to the case of BPA, the
218
structure of BPS was approximated to be 4-(methylsulfonyl)phenol (SI Table S1).
219
Accordingly, the species-specific rate constants of fully-dissociated BPA and BPS
220
could be predicted by eq 8 from their Hammett σ- constants (-0.13 for BPA and 1.13
221
for BPS) (Lee and Von Gunten 2012). Lee and von Gunten (2012) reported that the
222
species-specific rate constant of fully-dissociated BPA could be also well predicted by
223
the QSAR (eq 8). This was consistent with two independent studies, where BPA was
224
transformed by chlorine via electrophilic substitution pathway as confirmed by the
225
formation of chlorinated BPA (Gallard et al. 2004, Hu et al. 2002). However,
226
according to eq 8, the value of k3 for BPS was predicted to be in the range of
227
0.019-0.37 M-1 s-1, at least four orders of magnitude lower than the experimental one
228
(4.0 ± 0.14) × 103 M-1 s-1. A similar result was also obtained in a recent study on
229
chlorination of TBrBPA, and the underestimation was explained by that TBrBPA was
230
transformed by chlorine via electron transfer rather than electrophilic substitution as
231
confirmed by product analysis (Gao et al. 2016). So, it seemed likely that oxidative
232
pathway might be also involved in chlorination of BPS leading to the underestimation
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11
ACCEPTED MANUSCRIPT of k3 by the QSAR (eq 8), possibly due to the withdrawing effect of sulfur in BPS
234
structure (see the following section).
235
3.3. Identification of Transformation Products
236
Figure 2 showed the HPLC/ESI-QTOF-MS chromatogram of a sample containing
237
BPS treated by chlorine at pH 7. As can be seen, six new peaks appeared as compared
238
to the control one. Product I eluting at 19.31 min had a molecular ion of 282.983. On
239
the basis of its accurate mass and isotopic pattern (SI Figure S2), the molecular
240
formula of product I was assigned as C12H8SO4Cl (i.e., [C12H9SO4Cl-H]-). It was
241
further proposed to be mono-chloro BPS in accordance with its major fragments ions
242
of 18 (H2O), 36 (HCl), 126 (C6H3ClO) and 157(C6H5SO3) (SI Figure S3). Products II
243
and III eluting at 20.46 and 20.71 min had the same molecular ion of 316.944,
244
indicating they were structural isomers. Their molecular ions displayed isotopic
245
patterns identical to the molecular formula of C12H7SO4Cl2 (i.e., [C12H8SO4Cl2-H]-)
246
(SI Figure S4). The fragment ions of product II in the product ion spectra apparently
247
included m/z 36 (HCl), 157 (C6H5SO3,) 160 (C6H2Cl2O) (SI Figure S5). So, product II
248
was supposed to be 2,6-dichloro-BPS. Product III was suggested to be
249
2,6’-dichloro-BPS in accordance with its fragment ions of 36 (HCl), 126 (C6H3ClO),
250
and 191 (C6H4SO3Cl) (SI Figure S6). Product IV at 21.12 min had a molecular ion of
251
126.996 corresponding to molecular formula of C6H4OCl (i.e., [C6H5OCl-H]-) (SI
252
Figure S7). It was further assigned to be 4-chlorophenol (4CP) according to its
253
fragment ions of 36 (HCl) and 91 (C6H3O), which was confirmed by its analytical
254
standard (SI Figure S8). Product V at 21.80 min had a molecular ion of 350.905,
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12
ACCEPTED MANUSCRIPT corresponding to molecular formula of C12H6SO4Cl3 (i.e., [C12H7SO4Cl3-H]-) (SI
256
Figure S9). It was further supposed to be trichloro-BPS on the basis of fragment ions
257
of 36 (HCl), 126(C6H3ClO), 160 (C6H2Cl2O), and 191 (C6H4SO3Cl) (SI Figure S10).
258
Product VI eluting at 23.05 min had a molecular ion of 384.866, exhibiting isotopic
259
patterns identical to the molecular formula of C12H5SO4Cl4 (i.e., [C12H6SO4Cl4-H]-)
260
(SI Figure S11). It was further assigned to be tetrachloro-BPS in accordance with its
261
fragment ions of 36 (HCl), 160 (C6H2Cl2O), and 225 (C6H2SO3Cl) (SI Figure S12).
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It should be noted that not all transformation products could be detected as
263
chromatographic peak by visual inspection against the baseline of the chromatogram
264
because of their different abundances and response values (Baena-Nogueras et al.
265
2017, Gulde et al. 2016). Therefore, the Analytics software (AB Sciex) was further
266
applied to pick up possible products through suspect analysis on the basis of accurate
267
mass measurement, specific fragments, as well as comparison of theoretical and
268
measured isotopic patterns. As a consequence, additional five products (VII-XI) were
269
identified. Products VII and VIII were isomeric dimers of BPS. Product IX was
270
assigned to be 4-hydroxybenzenesulfonic acid (BSA), which was further confirmed
271
by its analytical standards. Products X and XI were proposed to be mono- and
272
dichloro-BSA, respectively. In order to confirm this, transformation products of BSA
273
treated by chlorine were detected and the chromatogram was shown in SI Figure S13,
274
where products X and XI were obvious. In summary, a total of eleven products were
275
identified in chlorination of BPS and their detailed information including retention
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277
in Table 1.
278
3.4. Proposed Reaction Pathways
279
On the basis of identified products, transformation pathways for chlorination of BPS
280
were tentatively proposed as shown in Figure 3. BPS was initially attacked by
281
chlorine substitution with the formation of monochloro-BPS (product I), which
282
subsequently underwent stepwise substitution reactions leading to the generation of
283
di/tri/tetrachloro-BPS (products II, III, V, and VI). Similar chlorine electrophilic
284
substitution was also reported in chlorination of BPA (Gallard et al. 2004). This
285
transformation pathway (pathway i) is consistent with the fact that electrophilic
286
substitution is a main chlorination pathway for aromatic rings (Deborde and Von
287
Gunten 2008, Gallard et al. 2004, Lee and Morris 1962). In addition, an oxidative
288
pathway (pathway ii) was proposed to account for the formation of 4CP (product VI),
289
dimers (prdocuts VII and VIII) and BSA (product IX): the phenol moiety of BPS was
290
initially oxidized by chlorine with the formation of a phenoxy radical R1. Then radical
291
R1 coupled to each other with the formation of dimers (products VII and VIII), or
292
cleavaged to release R2 radical and R3 cation. Subsequently, R2 radical was further
293
transformed to 4CP (product IV). R3 intermediate underwent substitution reactions to
294
generate BSA (product IX), which might be further attacked by chlorine substitution
295
with the generation of chlorinated BSA (product X and XI). Similar transformation
296
pathway ii was also reported in TBrBPA oxidation by chlorine (Gao et al. 2016).
297
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Kuruto-Niwa
et
al.
(2005)
reported 14
that
chlorinated
BPS
(i.e.,
ACCEPTED MANUSCRIPT mono/di/tri/tetrachloro-BPS) showed a substantially lower estrogenic activity
299
compared to BPS using a green fluorescent protein expression system, in contrast to
300
the findings that chlorinated BPA exhibited higher estrogenic activity compared to
301
parent BPA. In addition, the estrogenic activity of 4-CP was found to be very low as
302
reported by Nishihara et al. (2000). By testing the estrogenic activity of more than 500
303
chemicals, Nishihara et al. (2000) concluded that the estrogen activity of substituent
304
phenolics was positively related to their hydrophobic moiety at the para-position. So,
305
several oxidative products of BPS by chlorine (e.g., BSA and its chlorinated
306
derivatives) are expected to show an appreciably low estrogenic activity due to
307
hydrophilicity of sulfonic group. Therefore, it seems likely that chlorine treatment
308
may also eliminate estrogenic activity induced by BPS, which warrants further
309
verification by laboratory tests.
310
3.5. Effect of HA on Chlorination of BPS
311
3.5.1. Effect of HA on Reaction Kinetics.
312
Kinetic experiments were conducted to assess the effect of HA (0.5-2mgC/L) during
313
chlorination (30 µM) of BPS (1 µM) at an environmentally relevant pH 7. Figure 4
314
exhibited the time course profiles of BPS degradation and chlorine loss, respectively.
315
As can be seen, the presence of HA appreciably suppressed the degradation of BPS.
316
With the concentration of HA increasing from 0 to 2 mg C/L, the extent of BPS loss
317
greatly decreased from 86% to 46% at 15 minute. HA could competitively consume
318
oxidant thus leading to the decrease of degradation rates (Gallard et al. 2004, Yang et
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15
ACCEPTED MANUSCRIPT 319
al. 2014). In order to account for this effect, eq 9 was introduced to quantify the
320
kinetics Ct
321
C0
=exp{ -k
t 0
HOCl dt }
(9)
where Ct was the concentration of BPS at a specific time t, C0 was the initial
323
concentration of BPS, and
324
over time (i.e., chlorine exposure). It was found that the predictions made according to
325
eq 9 considerably overestimated the level of BPS loss in the presence of HA (SI
326
Figure 14). In addition, the transformation rate constants (k) at different
327
concentrations of HA could be obtained by eq 9. As shown in Figure 5, the rate
328
constants (k) decreased with the increase of HA concentration. Similar inhibition was
329
also observed in chlorination of TBrBPA, which was reasonably explained by the fact
330
that TBrBPA phenoxyl radicals formed by one-electron chlorine oxidation were
331
competitively reduced back to its parent by HA. Interestingly, it was also found that
332
HA had negligible influence on the degradation of BPA by chlorine, where the
333
reaction proceeded via chlorine electrophilic substitution (Gao et al. 2016).
334
Considering the two-channel pathways involved in chlorination of BPS, we
335
tentatively proposed that HA inhibited the degradation of BPS by chlorine via
336
electron transfer (pathway ii), similar to the case of TBrBPA. In parallel, HA had
337
negligible effect on the depletion of BPS transformed via electrophile substitution
338
(pathway i), similar to the case of BPA.
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HOCl dt was the chlorine concentration integrated
339
A two-channel kinetic model was accordingly introduced to further characterize the
340
effect of HA. Contaminants (P) was transformed by chlorine with the formation of 16
ACCEPTED MANUSCRIPT intermediate P1 (via electron transfer) with a yield r and P2 (via electrophilic
342
substitution) with a yield (1-r) (eq 10). P1 would be competitively reduced by HA to
343
its original form P (eq 11), in addition to its further irreversibly transformation (eq
344
12).
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P+chlorine → rP1 +(1-r)P2 (10) k4
345
P1 +HA → P (11) k5
P1 → Products k6
347
(12)
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346
The reactions 10 and 11 were both second-order to reactants, where k4 represented the
349
rate constants in the absence of HA (eq 10), and k5 was the rate constants for the
350
reaction of intermediate P1 with HA (eq 11). k6 was the first-order rate constant for eq
351
12. Therefore, kinetic equations 13 and 14 could be obtained to describe the
352
degradation rate for P and the formation rate for P1, respectively. dP dt
356 357
358
(13)
=rk4 P chlorine -k6 P1 -k5 P1 HA
(14)
By making a steady-state assumption for [P1], eq 15 could be obtained:
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d P1 dt
dP
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=k4 P chlorine -k5 P1 HA
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dt
=k4 1-r+ k
rk6 5
P chlorine
HA +k6
(15)
Therefore, the rate constant in the presence of HA could be described as eq 16 kHA =k4 1-r+ k
rk6 5
HA +k6
= k4 1-r+ k5 k6
r HA +1
(16)
359
As can be seen in Figure 5, the two-channel kinetic model (eq 16) could fit the
360
experimental data well. The values of r and k5/k6 was estimated to 0.64(±0.02) and
361
1.66(±0.18), respectively. These results indicated that the contribution of electron
17
ACCEPTED MANUSCRIPT 362
transfer and electrophilic substitution pathway to BPS degradation was around 64%
363
and 36%, respectively.
364
3.5.2. Effect of HA on Products Formation. (i) products analysis. The effect of HA on the products formation during
366
chlorination of BPS was also investigated. No additional products were detected in the
367
presence of HA compared to the case in the absence of HA (data not shown). This
368
finding was similar to the scenario of chlorination of TBrBPA, where HA had
369
negligible impact on the products species either (Gao et al. 2016). The influence of
370
HA on products formation during oxidation processes (e.g., permanganate, ferrate,
371
and enzymatic catalysis) was also investigated in previous work but confounding
372
effects were reported (Gao et al. 2016, Li et al. 2017, Lu et al. 2015, Lu and Huang
373
2009, Lu et al. 2017). For instance, Li et al. (2017) reported that HA negligibly
374
influenced the products species in soybean-catalyzed oxidation of triclosan. On the
375
contrary, Feng et al. (2013) reported that HA affected the products species in
376
laccase-catalyzed oxidation of TBrBPA, where additional new products with large
377
molecular ions were detected in the presence of HA. It seemed likely that the effect of
378
HA on the products species was complex, which might be associated with the nature
379
of HA and the experimental conditions.
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Due to the complexity of HA molecular structure, model compounds with defined
381
structures were used to further explore the effect of HA. In previous work,
382
2-methoxyphenol was commonly used to mimic HA (Li et al. 2017, Lu and Huang
383
2009, Lu et al. 2017). For instance, Lu and Huang (2009) reported that the presence of 18
ACCEPTED MANUSCRIPT 2-methoxyphenol in laccase-catalysis oxidation of acetaminophen led to the formation
385
of a new product, resulting from the coupling of 2-methoxyphenol and
386
acetamionphenol phenoxy radicals. Similarly, cross-coupling products were also
387
detected in soybean peroxidase-catalysis oxidation of triclosan. In this work, a new
388
product with a molecular ion of 371.059 was detected when 2-methoxyphenol was
389
present during chlorination of BPS. This new product was likely generated from cross
390
coupling of BPS and 2-methoxyphenol phenoxy radicals (SI Figure 15). This finding
391
in turn confirmed the occurrence of oxidative pathway during chlorination of BPS.
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384
Interestingly, several studies reported that co-solvent methanol could affect the
393
product species during BPA or TBrBPA oxidation (e.g., by permanganate, ferrate,
394
manganese dioxide or enzymatic catalysis oxidation), which was also verified in this
395
work (SI Table S3) (Feng et al. 2013, Gao et al. 2016, Yang et al. 2014). Carbocation
396
intermediates of 4-isopropylphenol or 2,6-dibromo-4-isopropylphenol formed during
397
BPA or TBrBPA oxidation, underwent substitution reactions with methanol (other
398
than
399
2,6-dibromo-hydroxy-isopropyl methanol (SI Table S3). Similarly, a new product
400
with a molecular ion of 187.007 was detected in chlorination of BPS when methanol
401
was present. This new product was suggested
402
benzenesulfonate (SI Figure 16), which was derived from the substitution reaction of
403
methanol and R3 intermediate. This finding confirmed again the occurrence of
404
oxidative pathway during chlorination of BPS.
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392
to
generate
4-hydroxy-isopropyl
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water)
19
methanol
or
to be 4-hydroxy-methyl
ACCEPTED MANUSCRIPT (ii) products evolution. The time course profiles of transformation products of BPS
406
by chlorine in the absence vs presence of HA were comparatively monitored by the
407
HPLC/ESI-QqQ-MS at MRM mode (Figure 6). In the absence of HA, the
408
consecutive formation of chlorinated BPS (generated through chlorine electrophilic
409
substitution pathway) was followed by their decay as a function of time, where
410
mono/di/tri/tetrachloro-BPS reached their maxima at about 5, 8, 15, and 35 min,
411
respectively. As the reaction proceeded, tetrachloro-BPS became the only chlorinated
412
BPS congeners. 4CP (generated via electron transfer pathway) was gradually
413
accumulated within 15 min and then declined. The maximum yield of 4CP was
414
quantified by the authentic standard to be about ~2% with respect to BPS loss.
415
Unfortunately, the response values of BSA and polymeric products (also generated
416
via electron transfer pathway) were too low and thus the formation dynamics of BSA
417
and its chlorinated products as well as the two dimers were not followed.
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In the presence of HA, the formation of monochloro-BPS was also followed by its
419
decay along with the reaction time but the occurrence of its maxima was prolonged to
420
about 25 min. Dichloro-BPS and trichloro-BPS were gradually generated and then
421
reached plateaus, while tetrachloro-BPS was negligibly generated. In particular, the
422
maximum yield of monochloro-BPS was calculated to be ~0.53 by using peak areas
423
(i.e., dividing its peak area by the decreased peak area of BPS) due to the lack of
424
authentic standard, which was higher than that obtained in the absence of HA (~0.40).
425
Along with reaction time, 4CP slowly accumulated to a plateau and its maximum
426
yield was calculated to be about ~1.1%, lower than that obtained in the absence of HA
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20
ACCEPTED MANUSCRIPT (~2%). These findings that HA increased the yield of monochloro-BPS and decreased
428
the yield of 4CP were in consistent with the conclusion deduced from the two-channel
429
model, where BPS was transformed by two parallel pathways and HA could inhibit
430
the degradation of BPS via electron transfer pathway.
431
4. Conclusion
432
This work firstly investigated the transformation of BPS by chlorine including
433
kinetics, products, mechanism, and the effect of HA. The following conclusions were
434
obtained, which might improve the understanding of chlorine chemistry in water
435
treatment:
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Chlorine could effectively degrade BPS over a wide pH range from 5-10 with the
437
apparent second-order rate constants of 7.6-435.3 M−1s−1.With a typical chlorine
438
residual concentration of 2 mg/L, the half life time of BPS was calculated to be
439
around 0.94-3.2 min at pH 7-8.
440
Eleven products including chlorinated BPS (i.e., mono/di/tri/tetrachloro-BPS),
441
4CP, BSA, chlorinated BSA (i.e., mono/dichloro-BSA) and two dimers were
442
detected by HPLC/ESI–QTOF-MS. It was proposed that BPS was transformed by
444 445
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436
chorine via two parallel pathways including chlorine electrophile substitution and electron transfer pathways. The inhibitory effect of HA on BPS degradation was reasonably explained by a
446
two-channel kinetic model, where HA negligibly influenced electrophile
447
substitution while appreciably inhibited the degradation of BPS through electron
448
transfer via reversing BPS phenoxyl radical back to parent BPS. 21
ACCEPTED MANUSCRIPT HA had negligible impact on the product species in chlorination of BPS.
450
However, in the presence of 2-methoxyphenol, a new additional product was
451
generated via cross coupling of BPS and 2-methoxyphenol phenoxy radicals. In
452
the case of co-solvent methanol, 4-hydroxy-methyl benzenesulfonate derived
453
from the substitution reaction of methanol and an intermediate was generated.
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449
Acknowledgments
455
This work was supported by the National Natural Science Foundation of China
456
(51578203); the Funds of the State Key Laboratory of Urban Water Resource and
457
Environment (HIT, 2016DX13); and the Foundation for the Author of National
458
Excellent Doctoral Dissertation of China (201346).
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ACCEPTED MANUSCRIPT 460
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Sharma, J., Mishra, I.M., Dionysiou, D.D. and Kumar, V. (2015) Oxidative removal of Bisphenol A by UV-C/peroxymonosulfate (PMS): Kinetics, influence of co-existing chemicals and degradation pathway. Chemical Engineering Journal 276(Supplement C), 193-204. Song, Y., Jiang, J., Ma, J., Pang, S., Liu, Y., Yang, Y., Luo, C., Zhang, J., Gu, J. and Qin, W. (2015)
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ABTS as an Electron Shuttle to Enhance the Oxidation Kinetics of Substituted Phenols by Aqueous Permanganate. Environmental Science & Technology 49(19), 11764-11771. Staples, C.A., Dorn, P.B., Klecka, G.M., O'Block, S.T. and Harris, L.R. (1998) A review of the environmental fate, effects, and exposures of bisphenol A. Chemosphere 36(10), 2149-2173.
AC C
547 548 549 550 551 552 553 554 555 556 557 558 559 560 561 562 563 564 565 566 567 568 569 570 571 572 573 574 575 576 577 578 579 580 581 582 583 584 585 586 587 588 589 590
van Leerdam, J.A., Vervoort, J., Stroomberg, G. and De, V.P. (2014) Identification of unknown microcontaminants in dutch river water by liquid chromatography-high resolution mass spectrometry and nuclear magnetic resonance spectroscopy. Environmental Science & Technology 48(21), 12791-12799.
Vandenberg, L.N., Hauser, R., Marcus, M., Olea, N. and Welshons, W.V. (2007) Human exposure to bisphenol A (BPA). Reproductive Toxicology 24(2), 139-177. Vione, D., Fabbri, D., Minella, M. and Canonica, S. (2017) Effects of the antioxidant moieties of dissolved organic matter on triplet-sensitized phototransformation processes: Implications for the photochemical
modeling
of
sulfadiazine.
Water
Research.
https://doi.org/10.1016/j.watres.2017.10.020 Wenk, J., Von Gunten, U. and Canonica, S. (2011) Effect of dissolved organic matter on the transformation of contaminants induced by excited triplet states and the hydroxyl radical. 25
ACCEPTED MANUSCRIPT Environmental Science & Technology 45(4), 1334-1340. Wenk, J., Aeschbacher, M., Sander, M., Gunten, U.V. and Canonica, S. (2015) Photosensitizing and Inhibitory Effects of Ozonated Dissolved Organic Matter on Triplet-Induced Contaminant Transformation. Environmental Science & Technology 49(14), 8541-8549. Yamazaki, E., Yamashita, N., Taniyasu, S., Lam, J., Lam, P.K., Moon, H., Jeong, Y., Kannan, P., Achyuthan, H. and Munuswamy, N. (2015) Bisphenol A and other bisphenol analogues including BPS and BPF in surface water samples from Japan, China, Korea and India, pp. 565-572.
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Yang, B., Ying, G., Chen, Z., Zhao, J., Peng, F. and Chen, X. (2014) Ferrate (VI) oxidation of tetrabromobisphenol A in comparison with bisphenol A. Water Research 62, 211-219.
Yang, Y., Lu, L., Zhang, J., Yang, Y., Wu, Y. and Shao, B. (2014) Simultaneous determination of seven bisphenols in environmental water and solid samples by liquid chromatography –
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electrospray tandem mass spectrometry. Journal of Chromatography A 1328, 26-34.
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591 592 593 594 595 596 597 598 599 600 601 602 603 604
26
ACCEPTED MANUSCRIPT
Table1. Products of BPS transformed by chlorine Found at mass
Formular
BPS
17.77
249.0224
C12H10SO4
20.71
316.9444
C12H9SO4Cl
C12H8SO4Cl2
316.9445
C12H8SO4Cl2
21.12
AC C
IV
126.9957
Proposed structural
-1.2
O S O
HO
-0.9
O S
OH
O
-1.0
Cl 2
HO
3
1
4
6
5
O S O
3'
2'
4'
1'
5'
OH
6'
Cl
-0.8
Cl 2
HO
1.0
3
1
4
6
C6H5OCl
OH
Cl HO
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III
20.46
282.9835
M AN U
II
19.31
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I
Mass Error(ppm)
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Retention time
SC
Product number
HO
5
O S O
3'
2'
4'
1'
5'
6'
Cl
Cl
OH
ACCEPTED MANUSCRIPT
VII
18.76
20.08
497.0363
SC
384.8666
C12H7SO4Cl3
C12H6SO4Cl4
C24H18S2O4
497.0366
C24H18S2O8
-0.7
Cl
Cl O S O
HO
7.81
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IX
172.9915
OH Cl
-0.5
Cl
Cl O HO
S O
OH
Cl
-1.4
Cl
O S O
HO
OH HO
O S
OH
O
-0.8
O S O
HO
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VIII
23.05
350.9055
M AN U
VI
21.80
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V
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Table1(continuted)
OH O
O S O
OH
C6H6SO8
0.5
O HO S O
OH
ACCEPTED MANUSCRIPT
Table1(continuted)
-0.6
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SC
C6H4SO4Cl2
M AN U
240.9131
C6H5SO4Cl
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16.46
206.9523
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XI
13.60
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X
-1.4
O HO S O O HO S O
Cl OH
Cl OH Cl
ACCEPTED MANUSCRIPT
500
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300
-1 -1
kapp(M s )
400
SC
200
0 5
6
M AN U
100
7
8
9
10
pH
Figure 1. pH dependency of apparent second-order rate constants for the reactions of
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the model fit by eq 7.
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chlorine with BPS. Symbols represent measured data and the dashed line represents
ACCEPTED MANUSCRIPT
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BPS
2
SC
1
6
M AN U
5
﹡
﹡
﹡
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3 4
Figure 2. The HPLC/ESI–QTOF-MS chromatogram of a sample containing BPS treated by chlorine. Asterisks represent the impurities.
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Experimental condition: [BPS] = 10 µM, [chlorine] = 30 µM, and pH 7.
ACCEPTED MANUSCRIPT
Cl O S O
OH
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HO Cl
II
Cl
chlorine
OH
HO
Cl
I
O HO
S O
OH
Cl
Cl OH
O S O
HO
Cl
OH
Cl
Cl
VI
V
Cl
OH
III
O
BPS
chlorine HO
O S
HO
O
O
R1
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HO
H2O
S O
HO
O S O
O S O
O
O S OH O
HO
R3
HO
Cl
IV
R2
O
Electron transfer
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HO
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HO
O S
Cl
O S O
SC
HO
Cl
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Electrophilic substitution
O S O
HO
O S OCH3 O
HO
O S O
self-coupling
O
HO
VII
or
OH O S O
Cl
O HO S O
OH
X
IX CH3OH
Cl
O HO S O
OH Cl
XI
HO
OH
O S O
O
O S O
OH
VIII
OH
ACCEPTED MANUSCRIPT
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Figure 3. The proposed pathway for the reaction of chlorine with BPS.
[chlorine]t/[chlorine]0
0.8 0.6
HA=0mgC/L HA=0.5mgC/L HA=1mgC/L HA=2mgC/L
0.2 0.0
0
5
0.8 0.6
0.2 0.0
10
Time(min)
15
(b)
0.4
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[BPS]t/[BPS]0
1.0
(a)
SC
1.0
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ACCEPTED MANUSCRIPT
0
HA=0mgC/L HA=0.5mgC/L HA=1mgC/L HA=2mgC/L
5
10
15
Time(min)
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1 µM, [chlorine] = 30 µM, and pH 7.
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Figure 4. The time course profiles of BPS degradation (a) and chlorine loss (b) at different HA concentrations. Experimental condition: [BPS]=
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ACCEPTED MANUSCRIPT
SC M AN U
90
-1
k(M s-1)
120
30 0.0
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60
0.5
1.0
2
R =0.99
1.5
2.0
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HA (mgC/L)
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Figure 5. HA concentration dependency of measured second-order rate constants for the reaction of chlorine (30 µM) with BPS (1 µM) at pH 7. Symbols represent measured data and the dashed line represents the model fit by eq 16.
0
0 0
25
50
75
100
3
1
0
0
25
-2
SC
2
20000
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Time (min)
product I product II product III product IV product V
concentration (×10 µΜ)
1 20000
40000
M AN U
40000
60000
-2
2
80000
Area
Area
60000
(b)
3
concentration (×10 µΜ)
product I product II product III product IV product V product VI
(a)
80000
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0 50
75
100
Time (min)
Figure 6. The evolution profiles of identified products of BPS by the treatment of chlorine in the absence (a) and presence of HA (b).
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Experimental condition: [BPS]= 1 µM, [chlorine] = 30 µM, [HA] = 2 mgC/L, and pH 7
ACCEPTED MANUSCRIPT Highlights: BPS could be effectively degraded by chlorine over pH of 5-10 (kapp 7.6-435.3 M−1s−1) A total of eleven products were detected by HPLC/ESI-QTOF-MS
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Two parallel pathways (electrophilic substitution & electron transfer) were proposed Inhibitory effect of HA on degradation was explained by a two-channel kinetic model
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HA had negligible effect on product species in chlorination of BPS