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Overlooked Role of Sulfur-Centered Radicals During Bromate Reduction by Sulfite Junlian Qiao, Liying Feng, Hongyu Dong, Zhiwei Zhao, and Xiaohong Guan Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.9b01783 • Publication Date (Web): 01 Aug 2019 Downloaded from pubs.acs.org on August 1, 2019
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Overlooked Role of Sulfur-Centered Radicals During Bromate
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Reduction by Sulfite
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Junlian Qiaoa,b,c, Liying Fenga, Hongyu Donga, Zhiwei Zhaod, Xiaohong Guana,b,c*
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aState
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Environmental Science and Engineering, Tongji University, Shanghai 200092, P.R.
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China
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bShanghai
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China
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cInternational
Key Laboratory of Pollution Control and Resources Reuse, College of
Institute of Pollution Control and Ecological Security, Shanghai 200092, P.R.
Joint Research Center for Sustainable Urban Water System, Tongji
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University, Shanghai 200092, P.R. China
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dKey
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Ministry of Education, Chongqing University, Chongqing 400045, China
Laboratory of the Three Gorges Reservoir Region's Eco-Environment, State
13 14 15 16 17 18
*Author to whom correspondence should be addressed
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Xiaohong Guan, email:
[email protected]; phone: +86-21-65983869; Fax: +86-
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21-65986313.
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TOC Art
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Abstract In this work, the kinetics and mechanisms of the reductive removal of BrO3ˉ
25
by sulfite in air atmosphere were determined. BrO3ˉ could be effectively reduced by
26
sulfite at pHini 3.0–6.0 and the reduction rate of BrO3ˉ increased with decreasing pH.
27
The co-existing organic contaminants with electron-rich moieties could be degraded
28
accompanying with BrO3ˉ reduction by sulfite. The reaction stoichiometries of
29
−Δ[sulfite]/Δ[bromate] were determined to be 3.33 and 15.63 in the absence and
30
presence of O2, respectively. Many lines of evidence verified that the main reactions in
31
BrO3ˉ/sulfite system in air atmosphere included the reduction of BrO3ˉ to HOBr and its
32
further reduction to Brˉ, as well as the oxidation of H2SO3 by BrO3ˉ to form SO3ˉ and
33
its further transformation to SO4ˉ. Moreover, SO4ˉ rather than HOBr was determined
34
to be the major active oxidant in BrO3ˉ/sulfite system. SO3ˉ played a key role in the
35
over-stoichiometric sulfite consumption because of its rapid reaction with dissolved
36
oxygen. However, the formed SO3ˉ was further oxidized by BrO3ˉ in N2 atmosphere.
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BrO3 ˉ reduction by sulfite is an alternative for controlling BrO3 ˉ in water treatment
38
because it was effective in real water at pHini ≤ 6.0.
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INTRODUCTION
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Bromide (Brˉ) is widely present in water sources at concentrations ranging from
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~10 to >1000 μg L-1 in fresh waters and ~65 mg L-1 in seawater.1 Although bromide in
43
waters is commonly not a hazard to human health due to its low concentration, it can
44
be a major concern for water treatment because of its role in disinfection byproducts
45
(organobromine and bromate) formation during chemical disinfection and oxidation.2,3
46
Bromate (BrO3ˉ) is generally formed by the reaction of ozone and hydroxyl radicals
47
(HO) with naturally occurring Brˉ in drinking water during ozonation process.4
48
Moreover, it has been reported that BrO3ˉ could be also formed in other chemical
49
disinfection and oxidation treatments of
50
Co(II)/peroxymonosulfate,6
51
oxidation.9,10 Wastewater ozonation is also a potential BrO3ˉ source for surface
52
waters.11 Due to its genotoxicity and carcinogenicity,12,13 the drinking water standard
53
for BrO3ˉ is 10 μg L-1.14-16
metal
Brˉ-containing waters, e.g., UV/persulfate,5
oxides
(CuO/NiO)/HOCl,7,8
and
Fe(VI)
54
Three categories of methods have been developed for minimizing BrO3ˉ
55
concentration in finished drinking water,17 including BrO3ˉ precursor (Brˉ) removal,
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optimizing disinfection/oxidation process to minimize BrO3ˉ formation, and BrO3ˉ
57
removal prior to water distribution. Membrane separation as well as electrochemical
58
and adsorptive techniques have been adopted for Brˉ removal from drinking water
59
sources.18 Besides, several treatment options have been tested to minimize BrO3ˉ
60
formation during ozonation, namely ammonia addition, pH depression, HO radical
61
scavenging, and scavenging or reduction of hypobromous acid (HOBr) by organic 4
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compounds.19 However, either Brˉ removal or minimizing BrO3ˉ formation during
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ozonation may be not feasible due to complicated procedure, harsh conditions, and high
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maintenance costs.20 Thus, effective post-treatment technologies should be developed
65
to remove BrO3ˉ from drinking water. Many techniques, including ion exchange
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membrane,21 ultraviolet irradiation,22 photocatalysis,23 electroreduction,24 chemical
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reduction,25 activated carbon,26 and biodegradation27,28 have been developed for BrO3ˉ
68
removal in past decades. Recently, the sulfite-based advanced reduction process (ARP)
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(e.g., UV/sulfite system) has attracted much attention for the reduction of chlorinated
70
organics (e.g., monochloroacetic acid29 and 1,2-dichloroethane30), perfluorooctanoic
71
acid,31 and oxyanions (e.g., BrO3ˉ)32 due to its high reduction efficiency. The removal
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of BrO3ˉ in UV/sulfite system has been attributed to the formation of reactive species
73
including hydrated electrons (eaqˉ) and hydrogen atom radicals (H) but not sulfite
74
radicals (SO3ˉ).20,33 Considering the fast reaction between these reactive reductants and
75
dissolved oxygen (DO),34 UV/sulfite process should be conducted in oxygen-free
76
condition,32 which limited the practical application of this process. Additionally, the
77
UV exposure would inevitably increase energy input.
78
Compared with the UV/sulfite system, the removal of BrO3ˉ by sulfite alone
79
obviously has significant advantages of competitive price and easy operation, but it has
80
received little attention so far. Gordon et al. reported that BrO3ˉ (BrO3ˉ/Brˉ, E0 = 1.4
81
V35) could be reduced by sulfite with half-life of 25–259 min at pH 4.0–7.0 and the
82
final products were Brˉ and SO42ˉ, respectively.25 In that study, the authors reported
83
that the equation for reduction of BrO3- by sulfite was as follows (Eq. 1): 5
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BrO3― +3SO23 ― ↔3SO24 ― + Br ―
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Eq. 1
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However, the molar ratio of sulfite to BrO3ˉ used by these authors at pH 4.0–7.0
86
ranged from 5.02 to 22.14, which was much larger than the stoichiometry shown in Eq.
87
1, while the authors did not offer corresponding explanations.25 In addition, the authors
88
did not determine the influence of background matrix on the performance of BrO3ˉ
89
reduction by sulfite, which is crucial for real practice. NaBrO3 combined with NaHSO3
90
was also reported to be an excellent oxidizing agent under mild conditions, which could
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selectively oxidize alcohols, diols, and ethers and thus was used in organic synthesis,
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due to the generation of reactive bromine species (HOBr).36-38 However, Schlaf and his
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co-workers concluded that [H2O-Br]+ or Br+ rather than HOBr was the actual oxidizing
94
agent.39 Although the active oxidants formed during the reduction of BrO3ˉ by sulfite
95
are of debate, their generation may contribute to the over-stoichiometric consumption
96
of sulfite during the process of BrO3ˉ reduction by sulfite.
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It is well known that various transition metals can react with sulfite to generate
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unstable SO3ˉ, which is prone to oxidation by oxygen, resulting in the formation of
99
peroxymonosulfate radical (SO5ˉ) and sulfate radical (SO4ˉ) through chain
100
propagation steps.40-43 SO4ˉ can further react with H2O or OHˉ to generate HO.44
101
However, the involvement of these radicals in the process of BrO3ˉ reduction by sulfite
102
keeps unknown and warrants further investigation.
103
Therefore, experiments were carried out in this study to (1) determine the kinetics
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of BrO3ˉ reduction by sulfite and the reaction stoichiometry with the presence or
105
absence of oxygen, (2) identify the reactive species formed in BrO3ˉ/sulfite process by 6
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collecting electron spin resonance (ESR) spectra, performing quenching experiments,
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monitoring the oxidation products of probe organic contaminant, and kinetic modeling,
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as well as (3) evaluate the feasibility of BrO3ˉ removal by sulfite in real water.
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EXPERIMENTAL SECTION
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Chemicals and Reagents
111 112
A complete list of reagents is provided in Text S1 of the Supporting Information. Experimental Procedures
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Batch experiments were conducted in 150 mL beakers at 23 ± 2 °C under magnetic
114
stirring. Air-exposed working solutions containing BrO3ˉ were prepared and adjusted
115
to the desired initial pH value (pHini) using H2SO4 or NaOH. Reactions were then
116
initiated by adding NaHSO3 from a stock solution that was pre-adjusted to the same
117
pHini as working solution. Unless otherwise specified, no measures were taken to adjust
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pH during the reaction to observe the change of pH so as to delineate the release of
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protons arising from the reduction of BrO3ˉ by sulfite. Periodically, 5.0 mL sample was
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collected and rapidly transferred to a small beaker containing 100 μL H2O2 stock
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solution (100 mM) to quench the residual sulfite. Then the samples were filtered with
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0.22 µm filters before subject to analysis with ion chromatograph (IC). Separate
123
samples, without quenching with H2O2, were collected to analyze the residual sulfite
124
concentration. To evaluate the influence of dissolved oxygen (DO) on reactions,
125
reactions were conducted in N2-sparged solutions (30 min N2 sparging, DO < 0.10 mg
126
L-1) and the reactions proceeded under continuous N2 bubbling.
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The procedures of examining the degradation of various organic contaminants 7
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(phenol, acetaminophen (ACT), bisphenol A (BPA), carbamazepine (CBZ), atrazine
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(ATZ), benzoic acid (BA), nitrobenzene (NB), and norfloxacin (NOR)) during BrO3ˉ
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reduction by sulfite, quenching experiments, and formaldehyde formation when
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methanol was oxidized in BrO3ˉ/sulfite process are present in Text S2.
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To identify the transformation products, solutions containing 0.10 mM phenol
133
were prepared and treated by HOBr alone (0.436 mM) or BrO3ˉ/sulfite process (1.0 mM
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NaBrO3 and 10.0 mM NaHSO3) at pHini 4.0. Before analyzing the transformation
135
products with gas chromatography-mass spectrometer (GC-MS), samples were
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extracted and desalinated by solid phase extraction (SPE).
137
The influence of water matrix on reductive removal BrO3ˉ by sulfite was examined
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in three waters, Milli-Q water, tap water collected in our lab, and a water sample
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collected from Qingcaosha reservoir in Shanghai (pH = 7.6, DOC = 6.5 mg C L-1,
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[HCO3ˉ] = 0.18 mM, [Brˉ] = 41.88 μg L-1, [Clˉ] = 28.98 mg L-1, [NO3ˉ] = 4.61 mg L-
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1),
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the water sample from Qingcaosha reservoir was stored at 4 °C before used in
143
experiment.
144
at three different pHini levels (5.0, 6.0, 7.0). After filtration with 0.45 μm membrane,
All experiments were performed at least in duplicate, and the average values with
145
standard deviations are reported unless otherwise noted.
146
Analytical Methods and Kinetic Modeling
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The details of the analytical methods used in this study are present in Text S3.
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Based on the proposed mechanisms of BrO3ˉ reduction by sulfite, a kinetic model was
149
compiled to simulate the kinetic data to verify the proposed mechanisms and the details 8
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are shown in Text S4.45
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RESULTS AND DISCUSSION
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Kinetics of BrO3ˉ Reduction by Sulfite
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Figure 1 shows the kinetics of BrO3ˉ reduction by sulfite and Brˉ generation at
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pHini 3.0–7.0 in the air and N2 atmosphere. It should be noted that sulfite is used to refer
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to the equilibrium mixture of sulfurous acid (H2SO3), bisulfite (HSO3ˉ), and sulfite
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(SO32ˉ) while chemical formula is used when one specific species is referred to. As
157
shown in Figure S1, HSO3ˉ is the major sulfite species between pH 1.8–7.2, whereas
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5.93%, 0.63%, and 0.06% of sulfite exists as H2SO3 at pH 3.0, 4.0, and 5.0 respectively.
159
Under oxic conditions, the rate of BrO3ˉ reduction by sulfite decreased with increasing
160
pHini, and the amount of reduced BrO3ˉ at equilibrium dropped progressively from
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0.071 to 0.019 mM with increasing pHini from 3.0 to 7.0. Sulfite has been employed for
162
reductive dehalogenation but it was reported that the reductive dehalogenation rates
163
increased with increasing pH,46-48 which is very different from the influence of pH on
164
BrO3ˉ reduction by sulfite and indicates the different mechanisms of halogenated
165
organics and BrO3ˉ reduction by sulfite. The kinetics of BrO3ˉ reduction was also
166
determined at various sulfite concentrations at pHini 4.0. As the sulfite concentration
167
increased from 0.5 to 2.0 mM, the removal efficiency of BrO3ˉ increased from 18.64%
168
to 100% at equilibrium (Figure S2). The initial stage of BrO3ˉ reduction by sulfite at
169
pHini 4.0 could be well simulated by pseudo-first-order rate law (Figure S3a), and the
170
pseudo-first-order rate constant (kobs) was found to elevate from 0.014 to 0.41 min-1 as
171
the sulfite dosage increased from 0.5 to 2.0 mM. kobs increased exponentially with 9
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increasing sulfite dosage (Figure S3b), and the amount of reduced BrO3ˉ was always
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far below the theoretical value calculated from Eq. 1 open to the air (Figure S2),
174
implying that DO influenced the reduction of BrO3ˉ by sulfite.
175
Therefore, the kinetics of BrO3ˉ reduction by sulfite was also determined under
176
anoxic conditions at various pHini levels in this study (Figure 1). Similar to the case
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open to the air, the BrO3ˉ reduction rate by sulfite under anoxic conditions dropped with
178
increasing pHini. Interestingly, the rate of BrO3ˉ reduction by sulfite at pHini 3.0 under
179
anoxic conditions was greater than its counterpart open to the air while the reduction
180
rates of BrO3ˉ in the initial reaction stage at pHini 4.0–7.0 under anoxic conditions were
181
slower than those open to the air. Moreover, BrO3ˉ (0.10 mM) could be completely
182
transformed to Brˉ at pHini 3.0–5.0 under anoxic conditions while only partial removal
183
of BrO3ˉ (0.10 mM) could be achieved by 1.0 mM sulfite under oxic conditions at pHini
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3.0–7.0. However, the amount of removed BrO3ˉ was as low as 0.016 and 0.008 mM at
185
pHini 6.0 and 7.0, respectively, under anoxic conditions within 120 min. The different
186
behaviors of BrO3ˉ reduction by sulfite under oxic and anoxic conditions should be
187
ascribed to the influence of oxygen and the change of pH during reaction.
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BrO3― +3HSO3― ↔3SO24 ― + Br ― +3H +
Eq. 2
189
O2 +2HSO3― ↔2SO24 ― + 2H +
Eq. 3
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Since the major sulfite species in a solution prepared from sodium bisulfite is
191
HSO3ˉ at pH 3.0–7.0 (Figure S1), the oxidation of HSO3ˉ by either BrO3ˉ or O2 releases
192
H+ (Eqs. 2–3),49 resulting in a drop of pH. Comparing Figure 1 and Figure S4, it could
193
be concluded that H+ was released at a greater rate when BrO3ˉ was reduced at a greater 10
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rate and the decrease in pH would in turn facilitate the abatement of BrO3ˉ by sulfite.
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When pHini was 3.0, pH gradually dropped to 2.75 and 2.85 under oxic and anoxic
196
conditions, respectively. Since the pH variation in these two conditions was very similar,
197
the slower BrO3ˉ reduction under oxic conditions at pHini 3.0 should be mainly ascribed
198
to the influence of oxygen. However, at pHini 4.0–5.0, pH under oxic conditions
199
dropped much faster than that under anoxic conditions, which may contribute to the
200
more rapid BrO3ˉ reduction under oxic conditions. It should be noted that BrO3ˉ
201
reduction experienced a lag phase before a rapid disappearance kinetics was observed
202
at pHini 5.0 under anoxic conditions. The self-accelerating behavior of BrO3ˉ reduction
203
by sulfite under this condition should be ascribed to the accumulation of H+, released
204
from the reduction of BrO3 ˉ by HSO3 ˉ (Eq. 2), in solution. When pHini was further
205
increased to 6.0–7.0, pH experienced little change under anoxic conditions compared
206
to the case under oxic conditions. Consequently, little BrO3ˉ was reduced under anoxic
207
conditions at pHini 6.0–7.0 within 120 min.
208
To verify the critical role of pH in the BrO3ˉ reduction process, experiments were
209
conducted at pH 3.0–5.0, where pH was maintained constant by dropwise addition of
210
NaOH. As shown in Figure S5, BrO3ˉ could be reduced by sulfite at pH 3.0–4.5 with
211
the reaction rate decreasing with increasing pH. Negligible BrO3ˉ was reduced by
212
sulfite at pH 5.0 within 30 min. It was reported that BrO3ˉ has a poor reactivity with
213
HSO3ˉ (𝑘BrO3― ,HSO3― = 0.027 ± 0.004 M-1s-1) but considerably greater reactivity with
214
H2SO3 (𝑘BrO3― ,H2SO3 = 85 ± 5 M-1s-1) at pH 4.6.50 As revealed by the species
215
distribution of sulfite at various pH values (Figure S1), the fraction of H2SO3 increases 11
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gradually from 0.06% to 5.93% as pH drops from 5.0 to 3.0, which indicated that H2SO3
217
rather than HSO3ˉ was the major species responsible for BrO3ˉ reduction.
218
Reaction Stoichiometry
219
The amount of BrO3ˉ reduction and sulfite consumption was quantified at pHini
220
4.0 under anoxic and oxic conditions to better elucidate the process of BrO3ˉ reduction
221
by sulfite. Figure 2a shows that the amount of residual BrO3ˉ dropped and that of the
222
Brˉ generation increased linearly with increasing sulfite doses (0–0.30 mM) when 0.10
223
mM BrO3ˉ was treated with varying sulfite doses for 4 h under anoxic conditions. The
224
applied sulfite was completely consumed within 4 h for all cases. The molar ratio of
225
consumed sulfite to reduced BrO3ˉ was determined to be 3.33 (−Δ[sulfite]/Δ[bromate])
226
and that of consumed sulfite to formed Brˉ was 3.23, which were close to the results
227
reported in literature (Eq. 2).50,51 Therefore, the reaction between BrO3ˉ and sulfite in
228
the absence of oxygen was basically in accordance with Eq. 2.
229
In the presence of oxygen, however, it was found that nearly all sulfite (0.25–1.50
230
mM) was consumed during its reaction with 0.10 mM BrO3ˉ at pHini 4.0 for 30 min and
231
−Δ[sulfite]/Δ[bromate] was as large as 15.63 (Figure 2b). In addition, the mass balance
232
of bromine indicates that Brˉ was the predominant reduction product of BrO3ˉ during
233
the reaction process. As shown in Figure S6, the change of DO concentration was < 0.2
234
mg/L when there was only sulfite, indicating that the direct oxidation of sulfite by DO
235
was very slow and did not contribute much to the over‐stoichiometric sulfite
236
consumption by BrO3ˉ in the presence of oxygen. Therefore, the over-stoichiometric
237
sulfite consumption by BrO3ˉ under oxic conditions should be mainly ascribed to the 12
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involvement of DO and the generation of reactive intermediates during the reaction of
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BrO3ˉ with sulfite (see the following sections).
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Identification of Reactive Intermediate Species
241
Since HOBr was reported to be easily generated from the reaction of NaBrO3 with
242
NaHSO3 for preparing bromohydrin derivatives,38 and HOBr was a requisite
243
intermediate in BrO3ˉ reduction,52-54 the possible generation of HOBr was investigated
244
in BrO3ˉ/sulfite process. However, negligible HOBr was detected within 30 min during
245
the reduction of BrO3ˉ by sulfite at pHini 4.0, which might be ascribed to the fast reaction
246
of HOBr with excess HSO3ˉ (𝑘HOBr,HSO3― = 1.0 × 109 M-1s-1)55. To further identify the
247
role of HOBr as an oxidant in BrO3ˉ/sulfite system, the decomposition of eight organic
248
contaminants by HOBr alone and BrO3ˉ/sulfite systems were compared (Figure S7).
249
HOBr is highly reactive toward phenolics1 and the removal efficiency of phenolics
250
(ACT, phenol, BPA) by HOBr oxidation was 85.0%–100%. Although the two systems
251
shared coincident oxidation selectivity for ACT, phenol, BPA, CBZ, and NB, the
252
different oxidation selectivity of HOBr and BrO3ˉ/sulfite system towards ATZ and BA
253
indicated that there is other reactive oxidant but not HOBr responsible for the oxidation
254
of specific contaminants (ATZ and BA) in BrO3ˉ/sulfite system.
255
Furthermore, phenol was selected as the model compound to investigate the
256
degradation products with the aim of identifying the role of HOBr. If HOBr was formed
257
in BrO3ˉ/sulfite system and was the major oxidant contributing to phenol oxidation, it
258
would lead to the formation of brominated products by electrophilic substitution
259
reaction.56 Thus, the degradation products of phenol in HOBr alone and BrO3ˉ/sulfite 13
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system were identified based on the full scan mode obtained from the GC-MS analysis.
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When 0.10 mM phenol was oxidized by 0.436 mM HOBr, four brominated phenolic
262
compounds were detected (Figure S8a). However, no brominated transformation
263
product was observed in BrO3ˉ/sulfite system (Figure S8b). In addition, there were
264
several polycyclic compounds with fully or partially unsaturated rings formed in
265
BrO3ˉ/sulfite system. These results confirmed that HOBr was not the major active
266
oxidant contributing to phenol decomposition in BrO3ˉ/sulfite system.
267
Additionally, in BrO3ˉ/sulfite system, 99.5% ATZ and 36.5% BA were degraded
268
at pHini 4.0 in air atmosphere, but negligible degradation for ATZ and BA in N2
269
atmosphere was observed (Figure S9), indicating that the degradation of ATZ and BA
270
was dependent on DO. It is well known that oxygen plays an important role in sulfur-
271
centered radical propagation reactions,57 which thus affects the oxidation of organic
272
contaminants. Therefore, the reactive sulfur free radicals were expected to generate in
273
BrO3ˉ/sulfite system.
274
To provide direct evidence for the generation of free radical species in the process
275
of BrO3ˉ reduction by sulfite, ESR spectra were collected with DMPO as a spin trap.
276
The signal with the hyperfine coupling constants (αN = 14.43 G, αβ ― H = 15.83 G)
277
was observed in ESR spectra with the addition of 100 mM DMPO before the initiation
278
of reaction at pHini 4.0 and 2.5 (Figures 3a and S10a), which was consistent with those
279
reported previously for DMPO-SO3ˉ adducts58,59. Furthermore, the signal of DMPO-
280
SO3ˉ adduct was not observed in the ESR spectra collected at pHini 7.2 (Figure S10b)
281
when HSO3ˉ and SO32ˉ are the major sulfite species (Figure S1). Thus, it could be 14
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concluded that SO3ˉ mainly arose from the reduction of BrO3ˉ by H2SO3.
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Because SO3ˉ reacts rapidly with DO at a diffusion-controlled rate (2.5 × 109 M-
284
1s-1)
285
HO,41 the evolution of DO concentration can also provide an evidence for SO3ˉ
286
generation. It was observed that the concentration of DO dropped rapidly from 8.97 to
287
3.08 mg L-1 within 10 min (Figure S6), confirming the participation of oxygen in the
288
chain reactions involving SO3ˉ. Subsequently, the DO concentration rebounded
289
increasingly, which should be mainly ascribed to the depletion of sulfite and dissolution
290
of oxygen from the overlying air.
to form reactive radicals SO5ˉ, which will be further transformed to SO4ˉ and
291
The signals arising from other radicals (SO4ˉ and HO) were not observed in the
292
ESR spectra (Figure 3a), because excess DMPO (100 mM) trapped all of the formed
293
SO3ˉ and terminated the subsequent radical propagation reactions. In order to trap
294
secondary radicals formed from the SO3ˉ chain reactions, 100 mM DMPO was added
295
after initiating the reaction for 30 min. As depicted in Figure 3b, typical DMPO-SO4ˉ
296
and DMPO-HO signals are observed, indicating the formation of secondary radicals in
297
BrO3ˉ/sulfite system. However, SO4ˉ-adducts can react with H2O/OHˉ via nucleophilic
298
substitution reaction to yield the corresponding HO-adducts at a considerably fast
299
reaction rate (e.g. t1/2 of DMPO-SO4ˉ = 95 s in water).60,61 Thus, the signal of HO can
300
be mainly attributed to the transformation of DMPO-SO4ˉ to DMPO-HO via
301
nucleophilic substitution and the formation of HO in BrO3ˉ/sulfite system needs further
302
verification.
303
To identify the principal reactive radicals in BrO3ˉ/sulfite system, EtOH and TBA 15
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were selected as radical quenchers. EtOH readily reacts with SO4ˉ (𝑘SO4 ― ,
305
× 107–7.7 × 107 M−1s−1) and HO (𝑘HO,EtOH = 1.2 × 109–2.8 × 109 M−1s−1),34,44 while
306
TBA has a poor reactivity with SO4ˉ (𝑘SO4 ― ,
307
considerably good reactivity with HO (𝑘HO,TBA = 3.8 × 108–7.6 × 108 M−1s−1).34,44 The
308
inhibitory effect of EtOH and TBA on phenol degradation in BrO3ˉ/sulfite system was
309
thus investigated at pHini 4.0 (Figure 3c). Theoretically, the oxidation of 5.0 μM phenol
310
by HO and SO4ˉ should be almost completely inhibited by 2.5 mM TBA ((𝑘HO,phenol
311
× [phenol])/(𝑘HO,TBA × [TBA]) ≤ 3.47%) and by 55 mM EtOH ((𝑘SO4 ― ,phenol ×
312
[phenol])/(𝑘SO4 ― ,EtOH × [EtOH]) ≤ 5.00%), respectively. The ratios and the rate
313
constants used to calculate them were listed in Table S2. It was found that the dosing
314
of 2.5 mM TBA only resulted in a slight drop of the degradation rate of phenol in BrO3ˉ
315
/sulfite system from 0.31 min-1 to 0.28 min-1 while the application of 55 mM EtOH
316
almost completely inhibited the degradation of phenol (Figure 3c). These phenomena
317
indicated that SO4 ˉ rather than HO was the predominant oxidant in BrO3 ˉ /sulfite
318
system. NB was also selected as a chemical probe of HO, because of its high reaction
319
rate constant with HO (𝑘HO ,NB = 3.9 × 109 M−1s−1) but very low reaction rate constant
320
with sulfate radical (𝑘SO•4 ― ,NB ≤ 106 M−1s−1).34,62 NB loss in the two systems was
321
negligible over 30 min at pHini 4.0, which also indicated that the formation of HO was
322
negligible in BrO3ˉ/sulfite system (Figure S7).
TBA
EtOH
= 1.6
= 4.0 × 105–9.1 × 105 M−1s−1) but
323
Based on the results of quenching experiments and the degradation of chemical
324
probe (NB), a preliminary conclusion could be obtained that SO4ˉ was the dominant
325
reactive oxygen species in BrO3ˉ/sulfite system. To further prove the production of 16
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SO4ˉ, 5.0 mM methanol was added to scavenge SO4ˉ and the oxidation product,
327
formaldehyde, was detected in BrO3ˉ/sulfite system.63 As shown in Figure 3d, no
328
formaldehyde was detected in the absence of sulfite. However, the concentration of
329
formaldehyde increased linearly with reaction time, and approximately 6.7 μM
330
formaldehyde was produced at the end of reaction, which also provided evidence for
331
the generation of SO4ˉ in BrO3ˉ/sulfite system.
332
Effect of Co-existing Organic Contaminants
333
Considering the degradation of co-existing organic contaminants in BrO3ˉ/sulfite
334
system in air atmosphere, the influence of phenol (0–100 μM) and NB (100 μM) on the
335
BrO3ˉ transformation was examined (Figure 4). The influence of 5.0 μM phenol on
336
BrO3ˉ reduction was negligible and the reduction of BrO3ˉ after 10 min was minor.
337
Although the presence of 100 μM phenol had little influence on BrO3ˉ reduction within
338
5 minutes, the reduction of BrO3ˉ was remarkably enhanced at longer time (Figure 4a
339
and 4b). To further clarify the roles of co-existing organic contaminants, the
340
concentrations of sulfite during the reaction process were determined accordingly. As
341
shown in Figure S11, the consumption kinetics of sulfite was only slightly affected by
342
5.0 μM phenol and sulfite was nearly depleted within 10 min, leading to minor BrO3ˉ
343
removal after 10 min. However, the consumption of sulfite was greatly retarded with
344
excess phenol (100 μM), which may be ascribed to the competition of excess phenol
345
with sulfite for reactive species and thus less consumption of sulfite. The significant
346
amount of residual sulfite in the presence of 100 μM phenol contributed to the
347
continuous reduction of BrO3ˉ after 10 min. Due to the negligible reactivity of NB in 17
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BrO3ˉ/sulfite system (Figures 4c and S7), it will not scavenge species that destroy
349
HSO3ˉ, so its presence had little effect on BrO3ˉ degradation.
350
Proposed Reaction Mechanism
351
Table 1 and Table S3 show the major proposed reactions in BrO3ˉ/sulfite system
352
under oxic and anoxic conditions. Since ESR spectra (Figures 3a, S10a, and S12)
353
revealed the generation of SO3ˉ in BrO3ˉ/sulfite system in both air and N2 atmosphere,
354
it was proposed that the reduction of BrO3ˉ by sulfite was initiated by the reaction of
355
BrO3ˉ with H2SO3 via one-electron transfer, leading to the formation of SO3ˉ and BrO2
356
(R1 and R1a), independent on the presence of DO. Concomitantly, in the presence of
357
DO, SO3ˉ reacted rapidly with DO at a diffusion-controlled rate to form SO5ˉ (R5),
358
which further reacts with HSO3 ˉ and produces SO4 ˉ (R6). Furthermore, the other
359
reactions (R7-R12) involved in the transformation of sulfur were listed, which have
360
been proposed in the literature.41 SO4ˉ is the active oxidant responsible for phenol
361
degradation (R13), which agrees well with the results of quenching experiments, ESR
362
spectra, and formaldehyde generation. In the absence of oxygen, the reaction of BrO3ˉ
363
reduction by SO3ˉ need to be considered to explain the observed reaction stoichiometry.
364
However, the self-combination of sulfite radicals to form dithionate is expected to play
365
a negligible role due to the low steady-state concentration of radicals.
366
The
formed
BrO2
was
further
reduced
to
BrO2ˉ
by
HSO3ˉ
and
367
the disproportionation of BrO2 was also considered in the kinetic model (R14, R5e, R15,
368
and R6f). Then, the unstable BrO2ˉ was quickly transformed to HOBr by HSO3ˉ (R16
369
and R7g ). It was found that the formed HOBr could be further reduced by HSO3ˉ with 18
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rate constant of 1.0 × 109 M-1s-1 (R17 and R8h). Consequently, the accumulation of
371
HOBr and its contribution to phenol oxidation is negligible, which was consistent with
372
the negligible formation of brominated byproducts and non-observation of HOBr
373
during the reaction.
374
It should be specified that the decomposition of H2SO3 to SO2 and the oxidation
375
of HSO3ˉ to SO42ˉ by O2 could not be neglected (R2, R2b, and R3). As illustrated in
376
Figure S13, the total amount of measured sulfite and sulfate (SO32ˉ, HSO3ˉ and SO42ˉ)
377
decreased to 0.74 mM and 0.97 mM, respectively, when the solution containing 1.0
378
mM sulfite was stirred alone open to the air at pHini 3.0 and pHini 4.0 for 30 min.
379
Considering the conversion of substantially all H2SO3 and aqueous SO2 to a mixture of
380
HSO3ˉ and SO32ˉ during analysis, the substantial loss of total sulfur species should be
381
due to the escape of SO2 gas from the solution. Besides, some HSO3ˉ will be converted
382
to H2SO3 as pH is lowered (R4 and R3c).
383
Kinetic Simulation
384
A kinetic model was developed based on the reactions and the corresponding rate
385
constants summarized in Table 1 and was used to simulate the experimental data. The
386
details of the kinetic model were described in Text S4. Under oxic conditions, as shown
387
in Figure 4, the kinetics of BrO3ˉ reduction and Brˉ formation could be well simulated
388
with the kinetic model in the absence of co-existing organic contaminants. Furthermore,
389
the kinetic model could successfully simulate the BrO3ˉ reduction, the Brˉ formation,
390
as well as the degradation kinetics of organic contaminants in the presence of 5.0 μM
391
phenol or 100 μM NB. Although the kinetic model slightly underestimated the effect 19
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392
of 100 μM phenol on the kinetics of BrO3ˉ reduction and Brˉ formation, it showed a
393
correct trend. However, the degradation kinetics of phenol at high concentration (100
394
μM) could not be simulated well (not shown) because abundant degradation products
395
of excess phenol were expected to generate in BrO3ˉ/sulfite system but were not
396
included in the kinetic model. Nevertheless, the kinetic model could well simulate
397
phenol degradation at low concentration (5.0 μM) because the trace amounts of formed
398
degradation products had little effect on the model (Figure 4c). Another kinetic model
399
was developed to simulate the experimental data under anoxic conditions based on the
400
reactions and the corresponding rate constants summarized in Table S3, and the kinetics
401
of BrO3ˉ disappearance and that of Brˉ generation were well simulated in the process
402
of BrO3ˉ reduction by sulfite at pHini 3.0 (Figure S14).
403
The influences of oxygen on the pathways of BrO3ˉ reduction and sulfur
404
transformation in BrO3ˉ/sulfite system are summarized in Figure 5. The rate constant
405
for the reaction of DO with SO3ˉ (R5, Table 1) is about 4 orders of magnitude larger
406
than that for the reaction of BrO3 ˉ with SO3 ˉ (R4d, Table S3). In addition, the
407
maximum concentration of DO (0.28 mM) is about 2.8 times higher than that of BrO3ˉ
408
(0.10 mM). Therefore, the reduction of BrO3ˉ by SO3ˉ is almost completely inhibited
409
in the presence of DO (𝑘R5[DO] ≫ 𝑘R4d[BrO3 ˉ]). A series of sulfur-centered radical
410
chain propagation reactions caused by DO led to the over-stoichiometric sulfite
411
consumption. However, in the absence of oxygen, the SO3 ˉ generated by the initial
412
reaction of H2SO3 with BrO3ˉ is further oxidized by BrO3ˉ, resulting in the
413
stoichiometry (−Δ[sulfite]/Δ[bromate]) following Eq. 2. 20
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ENVIRONMENTAL IMPLICATIONS
415
In this study, we proposed a reductive strategy to transform BrO3ˉ to Brˉ with
416
sulfite. Different from the eaqˉ-based reductive strategy, sulfite could effectively reduce
417
BrO3ˉ over a wide pH range of 3.0–6.0 in pure water open to the air. SO3ˉ was
418
generated during BrO3ˉ reduction by H2SO3, and HSO3ˉ was involved in the sulfur-
419
centered radicals chain propagation reactions. Several lines of evidence unraveled that
420
SO3ˉ was generated in BrO3ˉ/sulfite system and its rapid reaction with DO was the key
421
leading to the over-stoichiometric sulfite consumption. Organic contaminants with
422
electron-rich moieties can be effectively degraded in BrO3ˉ/sulfite system and SO4ˉ
423
rather than HOBr was determined to be the active oxidant. The effective removal of
424
BrO3ˉ (25.0 μg/L) in real water by sulfite at pHini ≤ 6.0 could be achieved (Figure S15),
425
indicating that this method was an alternative for controlling BrO3ˉ in water treatment.
426
As pHini is elevated to 7.0, the reduction of BrO3ˉ in tap water and source water by
427
sulfite is not efficient although that in Milli-Q water is effective, which should be
428
ascribed to large buffering capacity of tap water and source water, and thus causing
429
high pH during the reaction process. In sum, reductive removal of BrO3ˉ with sulfite is
430
low-energy and environmentally friendly. However, further research is needed to
431
broaden the applicable pH range of this approach and improve the performance of this
432
process in real waters, especially under neutral and weak alkaline conditions. The
433
influence of co-existing solutes on BrO3ˉ reduction by sulfite also warrants further study
434
so as to predict the performance of this technique in different real waters.
435
ASSOCIATED CONTENT 21
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436
Supporting Information
437
The Supporting Information is available free of charge on the ACS Publications website.
438
Texts S1–S4, Figures S1–S15, and Tables S1–S3.
439
AUTHOR INFORMATION
440
Corresponding Author
441
*Email:
[email protected];
442
Phone: +86-21-65983869;
443
Fax: +86-21-65986313.
444
Notes
445
The authors declare no competing financial interest.
446
ACKNOWLEDGMENTS
447
This work was supported by the National Natural Science Foundation of China
448
(Grant 21522704).
449
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450 451 452 453 454 455 456 457 458 459 460 461 462 463 464 465
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Concentration (mM)
(a) pHini 3.0
(b) pHini 4.0 0.10
0.10
0.08
0.08
0.08
0.06
0.06
0.06
0.04
0.04
0.04
0.02
0.02
0.02
0.00
0.00 0
5
10
15
20
25
0.00 0
30
10
20
Concentration (mM)
(d) pHini 6.0
30
40
50
60
0.10
0.10
0.08
0.08
0.06
0.06
0.04
0.04
0.02
0.02
0
20
40
60
80
100
120
Time (min)
(e) pHini 7.0
0.00
BrO3- (Air) Br -3(Air) BrO3- + Br - (Air) BrO3- (N2) Br -3(N2)
BrO3- + Br - (N2) Total Br
0.00 0
614 615 616 617 618
(c) pHini 5.0
0.10
20
40
60
80
Time (min)
100
120
0
20
40
60
80
100
120
Time (min)
Figure 1. Effect of dissolved oxygen (DO) on the kinetics of BrO3ˉ reduction by sulfite and that of Brˉ generation at different pHini levels. Reaction conditions: [NaBrO3]0 = 0.10 mM, [NaHSO3]0 = 1.0 mM.
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(a) w/o O2
(b) w/ O2 0.10
0.08
0.04
2
R = 0.99 Slope = 0.31
BrO3BrTotal Br
R2 = 0.98 Slope = -0.30
0.02 0.00 0.00
619 620 621 622 623 624
0.05
0.10
0.15
0.20
0.25
Concentration (mM)
Concentration (mM)
0.10
0.06
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0.08 0.06 0.04
R2 = 0.95 Slope = 0.065
BrO3BrTotal Br
R2 = 0.97 Slope = -0.064
0.02 0.00 0.00
0.30
0.25
Sulfite concentration (mM)
0.50
0.75
1.00
1.25
1.50
Sulfite concentration (mM)
Figure 2. Stoichiometries for the reaction of BrO3ˉ with sulfite in the absence of oxygen (a) and in the presence of oxygen (b). Reaction conditions: (a) pHini = 4.0, [NaBrO3]0 = 0.10 mM, [NaHSO3]0 = 0-0.30 mM, reaction time 4 h; (b) pHini = 4.0, [NaBrO3]0 = 0.10 mM, [NaHSO3]0 = 0-1.50 mM, reaction time 30 min.
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150
(a)
100
40
Intensity
Intensity
(b)
60
50 0
20 0
-50
-20
-100
-40
-150
-60 3340
3360
3380
3400
3340
Magnetic field (G)
3400
(d)
7.5 0.28 min-1
Formaldehyde (μM)
-1
kobs(min )
3380
Magnetic field (G)
(c) 0.31 min-1 0.32
3360
0.24 0.16 0.08
BrO3BrO3- /sulfite system
6.0 4.5 3.0 1.5
-1
0.01 min
0.00
625 626 627 628 629 630 631 632 633
No scavenger
TBA
0.0 0
EtOH
5
10
15
20
25
30
Time (min)
Figure 3. ESR spectra of DMPO-SO3ˉ (a), ESR spectra of DMPO-HO and DMPOSO4ˉ (b), effect of TBA and EtOH on kobs of phenol degradation (c), and the formation of formaldehyde (d) in air atmosphere. Reaction conditions: pHini = 4.0, [NaBrO3]0 = 0.10 mM, [NaHSO3]0 = 1.0 mM, (a) and (b) [DMPO]0= 100 mM, (c) [phenol]0 = 5.0 μM, [TBA]0 = 2.50 mM, [EtOH]0 = 55.0 mM, (d) [MeOH]0 = 5.0 mM. (● indicates DMPO-SO3ˉ adduct; ▲ indicates DMPO-HO adduct; ◆ indicates DMPO-SO4ˉ adduct).
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0.06
5 μM phenol 100 μM phenol 100 μM NB
0.04
-
0.02 0.00
0.06 0 μM phenol or NB 5 μM phenol 100 μM phenol 100 μM NB
0.04 0.02
5
10
15
20
Time (min)
25
30
35
(c)
5 4
0
5
10
15
20
25
30
35
Time (min)
100 99
5 μM phenol 100 μM NB
3
98
2
97
1
96
0
0.00 0
634 635 636 637 638 639
0.08
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NB concentration (μM)
0 μM phenol or NB
(b)
0.10
Phenol concentration (μM)
0.08
Br concentration (mM)
(a)
0.10
-
BrO3 concentration (mM)
Environmental Science & Technology
95 0
1
2
3 15
20
25
30
35
Time (min)
Figure 4. Simulation of BrO3ˉ removal (a), Brˉ formation (b) and contaminants degradation (c) in BrO3ˉ/sulfite system under oxic conditions. Symbols and dash lines represent measured data and the model simulations, respectively. Reaction conditions: pHini = 3.0, [NaBrO3]0 = 0.10 mM, [NaHSO3]0 = 1.0 mM.
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640 641 642 643 644
Environmental Science & Technology
Figure 5. Proposed pathways of BrO3ˉ reduction and sulfur transformation in BrO3ˉ/sulfite system. The pathway numbers (R1, R5, R6, R11, and R13-17) correspond to the reactions in Table 1 and the reaction equation and the rate constant of R4d is shown in Table S3.
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646 647
Table 1. The model equations and the corresponding rate constants in air atmosphere in BrO3ˉ/sulfite system. No. R1 R2 R3
648 649 650
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k (M-1 s-1)a
Reaction ˉ
Reference
210 This work -3 8.0 × 10 This work 11.24 This work 8 2.0 × 10 , 50,64 R4 HSO3ˉ + H+ ⇌ H2SO3 3.6 × 106 41 R5 2.5 × 109 SO3ˉ + O2 ⟶ SO5ˉ 3 + 2 R6 8.6 × 10 This work SO5 ˉ + HSO3ˉ ⟶ H + SO4 ˉ + SO4 ˉ 4 R7 3.6 × 10 This work SO5 ˉ + HSO3ˉ ⟶ HSO5ˉ+ SO3 ˉ 41 3 2 + R8 9.1 × 10 HSO5ˉ + HSO3ˉ ⟶ 2SO4 ˉ + 2H 7 41 R9 9.0 × 10 SO5 ˉ + SO5 ˉ ⟶ 2SO4 ˉ + O2 41 R10 SO5ˉ + SO5ˉ ⟶ S2O82ˉ + O2 1.3 × 108 8 41 2 + R11 SO4 ˉ + HSO3ˉ ⟶ H + SO4 ˉ + SO3 ˉ 7.5 × 10 41 R12 SO4ˉ + SO4ˉ ⟶ S2O82ˉ 5.0 × 108 65 9 R13 SO4 ˉ + phenol ⟶ products 8.8 × 10 R14 2BrO2 + HSO3ˉ + H2O ⟶ 2HBrO2 + SO42ˉ + H+ 7.5 × 109 This work 66 + R15 2BrO2 + H2O ⟶ HBrO2 + BrO3ˉ + H 4.2 × 107 55 R16 HBrO2 + HSO3ˉ ⟶ HOBr + SO42ˉ + H+ 3.0 × 107 9 55 2 + R17 HOBr + HSO3ˉ ⟶ Brˉ + SO4 ˉ + 2H 1.0 × 10 aSome rate constants were obtained from literatures (R4, R5, R8-13, and R15-17). The rate constants of R1-3, R6-7, and R14 were estimated based on fitting the experimental data with the constructed kinetic model to under specific conditions. BrO3ˉ + H2SO3 ⟶ SO3 + BrO2 + H2O H2SO3 ⟶ SO2 + H2O 2HSO3ˉ + O2 ⟶ 2H+ + 2SO42ˉ
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