Characterization of Brominated Disinfection Byproducts Formed

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Environmental Processes

Characterization of Brominated Disinfection Byproducts Formed During the Chlorination of Aquaculture Seawater Juan Wang, Zhineng Hao, Fengqiong Shi, Yongguang Yin, Dong Cao, Ziwei Yao, and Jing-fu Liu Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b05331 • Publication Date (Web): 27 Apr 2018 Downloaded from http://pubs.acs.org on April 27, 2018

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Characterization of Brominated Disinfection Byproducts

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Formed During the Chlorination of Aquaculture Seawater

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Juan Wang,

†‡









Zhineng Hao, Fengqiong Shi, #Yongguang Yin, Dong Cao, Ziwei Yao, §

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†#

and Jingfu Liu *

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State Key Laboratory of Environmental Chemistry and Ecotoxicology, Research

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Center for Eco-Environmental Sciences, Chinese Academy of Sciences, P. O. Box

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2871, Beijing 100085, China

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Institute of Environment and Health, Jianghan University, Wuhan 430056, China

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#

University of Chinese Academy of Sciences, Beijing 100049, China

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§

National Marine Environmental Monitoring Center, 42 Linghe Street, Shahekou

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District, Dalian 116023, China

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

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Fax: +86-10-62849192

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TOC/Abstract Art

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Abstract:

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Although brominated disinfection byproducts (Br-DBPs) have been reported to

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form from reactions between bromide, dissolved organic matter (DOM) and

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disinfectants, their formation during the disinfection of aquaculture seawater via

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chlorination has been rarely studied. Herein, after 5 days of disinfection of raw

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aquiculture

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trichloroisocyanuric acid (TCCA) and chlorine dioxide (ClO2), 181, 179 and 37

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Br-DBPs were characterized by ultra-high-resolution Fourier transform ion cyclotron

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resonance mass spectrometry (FT-ICR MS). Sunlight irradiation of the chlorinated

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aquaculture seawater with TCCA and NaDDC was found to reduce the formation of

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Br-DBPs, possibly due to the photodegradation of the important HBrO/HClO

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intermediate and the degradation of formed Br-DBPs. The formation of Br-DBPs

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chlorinated by ClO2 increased under sunlight irradiation. The number of Br-DBPs

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formed during chlorination processes agreed well with the total organic bromine

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(TOBr) content measured by inductively coupled plasma mass spectrometry

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(ICP-MS). Most of the Br-DBPs were highly unsaturated and phenolic compounds,

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which were primarily generated through electrophilic substitution by bromine coupled

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with other reactions. In addition, some emerging aromatic Br-DBPs with high relative

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intensities were also assigned, and these compounds might be highly lipophilic and

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could potentially accumulate in marine organisms. Our findings call for further focus

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on and investigation of the Br-DBPs produced in chlorinated aquaculture seawater.

seawater

samples

with

sodium

dichloroisocyanurate

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(NaDDC),

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INTRODUCTION

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Chlorine-containing disinfectants, such as chlorine, sodiumhypochlorite and

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chloramines, are commonly used in water disinfection treatments due to their

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outstanding performance in the removal of microorganisms, degradation of

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micropollutants, discoloration, and attenuation of taste and odor.1-4 However, these

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disinfectants can lead to the formation of harmful disinfection byproducts (DBPs)

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through reactions among the disinfectants, halide ions and natural organic matter

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(NOM).1, 5, 6 In general, brominated DBPs (Br-DBPs) are more concerned because of

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their higher cytotoxicity and genotoxicity relative to their chlorinated analogues.7, 8

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Trichloroisocyanuric acid (TCCA) and sodium dichloroisocyanurate (NaDDC),

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which are thought to be cleaner and safer than traditional disinfectants, have been

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used as alternative disinfectants for water disinfection, and their consumer demand

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has increased annually,9-11 which accounted for 8% of the disinfectants used in the

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aquaculture in China.12 During water disinfection, TCCA and NaDDC release

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hypochlorous acid (HOCl), which is the vital component of disinfection.9, 12 Chlorine

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dioxide (ClO2), another alternative disinfectant, has been extensively used in water

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disinfection, accounted for 20% of the disinfectants used in the aquaculture in

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China,12 due to its lower potential to form DBPs.13-16 Nevertheless, the use of these

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alternative disinfectants can still result in the formation of Br-DBPs. For example, the

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oxidation of Br− by HOCl produces hypobromous acid/hypobromite (HOBr/OBr−),

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which can subsequently react with the electron-rich moieties of NOM, such as

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phenols and olefins, to form Br-DBPs.1, 5, 17 4

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Currently, studies on the formation of Br-DBPs have mainly focused on the

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disinfection of drinking water and swimming pools, and very few studies have

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examined the disinfection of aquaculture seawater.18 However, the generation of

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Br-DBPs during aquaculture seawater disinfection should not be under estimated

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because of the extremely high concentration of bromide (67 mg L−1) in aquaculture

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seawater relative to that in freshwater sources (< 2 mg/L).4,

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seawater disinfection have shown that considerable amounts of Br-DBPs were

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generated in chlorinated seawater,18, 19 most of which contained aromatic structures.19

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More importantly, DBPs containing aromatic structures, which are more lipophilic

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with higher log P values (2.40−5.01) than aliphatic halogenated DBPs

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(0.43−1.79),20-22 more efficiently permeate cells and accumulate in marine

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organisms.20,23-25 For instance, high levels of polybrominated diphenyl ethers and

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brominated phenols were found in the blood of fish and wildlife from the Baltic Sea24,

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26

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and cats through the ingestion of pet food.26 In addition, nitrogenous DBPs, which are

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generally more toxic than carbonaceous DBPs,27 can also be produced in

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nitrogen-containing water during chlorination treatment and potentially accumulate in

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aquatic organisms.4,27 For instance, 2,2-dichloroacetamide has been confirmed to

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accumulate in zebrafish and cause metabolic damage.28

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Recent studies on

and in seafood,23 and these compounds were also determined to accumulate in dogs

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Given that the disinfection of aquaculture seawater is performed under the

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conditions of the natural environment, the effects of sunlight irradiation on the

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formation of Br-DBPs should be considered. Previous studies have reported that 5

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sunlight can cause the formation of organobromine compounds due to the production

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of reactive halogen species (RHS) in seawater.29, 30 Furthermore, sunlight can also

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lead to the degradation of HClO/ClO− and HBrO/BrO− to Cl− and Br−,31 as well as the

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degradation of these generated Br-DBPs,32,33 which would decrease the amount of

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DBPs produced. Therefore, studies on the formation of Br-DBPs during the

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disinfection of aquaculture seawater both in the dark and under sunlight irradiation are

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very important.

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Due to its extremely high mass accuracy and resolution, ultra-high-resolution

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Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) coupled

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with electrospray ionization (ESI) has been utilized as an emerging technique for

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identifying the complicated molecular compositions of NOM34, 35 and DBPs during

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water treatment.19, 36-38 Although FT-ICR MS is not able to quantify these compounds

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because of variations in the ionization efficiency of ESI under different conditions,

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the relative intensity (RI) of a peak, which is calculated by comparing the intensity of

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a specific peak with that of the most intense peak, can partially reflect the content of

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the specific substance.39 Inductively coupled plasma mass spectrometry (ICP-MS) has

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been employed as a sensitive tool for quantifying the total organohalogen content in

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seawater and human urine.40, 41

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The objective of this research was to study the formation of Br-DBPs in

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aquaculture seawater chlorinated by TCCA, NaDDC and ClO2 by utilizing

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ESI-FT-ICR MS. Special attention was paid to the impact of light irradiation, which

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strongly affects Br-DBP formation, by performing the disinfection of aquaculture 6

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seawater in the field where sunlight irradiation can vary tremendously. In addition, the

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total organic bromine (TOBr) concentration, a parameter used to evaluate the bulk

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organic bromine level in chlorinated aquaculture seawater, was measured by ICP-MS.

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This is the first study to identify and characterize the Br-DBPs generated in

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chlorinated aquaculture seawater using FT-ICR MS, and the results should be helpful

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for assessing the safety of the use of chlorine-containing disinfectants in aquaculture

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seawater.

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MATERIALS AND METHODS

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Chemicals and Water Sample Preparation. NOM (serial No. 2R101N) was

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purchased from the International Humic Substances Society (St. Paul, MN, US).

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Methanol (Optima grade) and formic acid (99%) were purchased from Fisher

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Scientific (Shanghai, China). Sodium bromide (≥ 99.5%) was purchased from

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Sigma-Aldrich (Saint Louis, MO, US). TCCA (analytical grade) and NaDDC

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(analytical grade) were purchased from Aladdin Reagent Company (Shanghai, China).

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Chlorine dioxide (ClO2) was purchased from Xiya Reagent Company (Shandong,

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China). Ultrapure water (18.2 MΩ) was obtained from a Milli-Q gradient system

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(Millipore, MA, US).

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Artificial seawater (ASW) was prepared according to the formula of

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Mendez-Díaz and Shimabuku,40 and the components were given in supporting

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information (Table S1). ASW was kept in darkness before exposure to disinfectants.

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Raw seawater samples (RSW), below the 30 cm of the water surface, which might

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undergo weak sunlight irradiation, were collected from aquaculture seawater farms in 7

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the northwest Huanghai Sea (N 39º48′ 2.81″, E119º26′36.42″), ambient temperature

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of 16 °C, then filtered through a 0.45 µm pore-size cellulose acetate membrane to

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remove the suspended particles, and stored in the dark at room temperature. RSW

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samples were immediately used after being taken from field seawater, thus microbial

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degradation and production had little effect on DOM compositions. The pH, Br− and

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dissolved organic carbon (DOC) content of RSWs was 8.2, ~0.82 mM and ∼4.0 mg C

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L−1, respectively, and the other characteristics of RSWs were listed in Table S1.

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Chlorination Experiment. The chlorination of RSW/ASW samples in the dark

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was performed in 1 L amber glass bottles wrapped with aluminum foil. The DOC and

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pH values of the ASW were 3.0 mg C L−1 and 8.0, respectively. All the initial

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concentrations of TCCA, NaDDC and ClO2 were 0.71 mg L−1 (available chlorine),

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which was approximately the recommended dosage for aquaculture disinfection. Then,

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all the samples were submerged in a 20 L water bath to maintain the reaction

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temperature at 25 ± 2 °C. At the same time, the water samples were magnetically

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stirred at 300 rpm to simulate the motion of aquaculture seawater. Control

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experiments were performed under the same conditions without disinfectants. Before

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chlorination, a 250 mL aliquot of the solution was sampled from each seawater

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sample. After 1, 3 and 5 d of chlorination, a 250 mL aliquot of the solution was

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sampled, and the reaction was immediately quenched by adding excess Na2S2O3 (100

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µM). In parallel, water samples were chlorinated under sunlight irradiation according

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to the same procedures performed in the dark, except that the samples were irradiated

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in a sunlight simulator (Beifanglihui Company, SN-500, Beijing, China), equipped 8

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with three 2500 W air-cooled Xe lamps. Specifically, UV-light with wavelengths

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below 290 nm was attenuated by insetting glass cutoff filters (2 cm below Xe lamps),

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and the light intensity was held steady at 550 W m−2. The emission spectrum of the

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simulated sunlight is given in the Supporting Information (Figure S1).

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Water Sample Pretreatment. The water samples were pretreated according to

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the procedure reported by Mendez-Díaz and Shimabuku.40 In brief, the water samples

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were preferentially acidified to approximately pH 2.0 by adding formic acid

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dropwise, and then the samples were concentrated and desalted by SPE. The main

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steps of sample pretreatment were as follows:(i) Bond Elut PPL SPE cartridges (6 mL,

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1 g, Agilent Technologies, Folsom, CA) were sequentially rinsed with two cartridge

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volumes of methanol and acidified ultrapure water (pH ∼ 2.0, acidified with formic

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acid); (ii) the acidified water samples were pumped through cartridges at a flow rate

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of ∼5 mL min−1 to accumulate the target compounds, after which the cartridges were

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desalted by rinsing with two cartridge volumes of acidified ultrapure water; (iii) the

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cartridges were dried with nitrogen gas and eluted with two cartridge volumes of

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methanol. The eluate was divided into 2 equal portions, freeze-dried and stored at

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-20 °C in the dark. One portion of the freeze-dried samples was diluted with a

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methanol/water solution (v/v, 50/50) to 1 mL for the detection of Br-DBPs. To

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measure the TOBr and TOC, the other portion of the freeze-dried sample was

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dissolved in 19 mL of ultrapure water, and then trace halide ions were removed by

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filtrating the sample through a Ba/Ag/H cartridge (2.5 mL, 2.2‒2.6 meq/cartridge,

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Dionex/Thermo Scientific, Sunnyval, Cal.). Before the measurement of the TOBr, 5% 9

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NH4OH (v/v) was added to the sample to minimize the accumulation of bromide in

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the spray chamber or on the nebulizer.

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FT-ICR MS analysis. A Bruker SolariX 15 Tesla (FT-ICR MS) was used to

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analyze the extracted Br-DBPs. The diluted sample was injected into the electrospray

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source at 2 µL min−1 using a syringe pump. The ESI voltage was set to -3.8 kV, and

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the mass range was set at m/z 150‒1000 Da. Ions were accumulated in the hexapole

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ion trap for 0.2 s before being introduced into the ICR cell. Three hundred mass

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spectra were averaged per sample. Each sample was measured three times to ensure

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the

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cross-contamination and sample carryover, the injection syringe and lines were

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washed three times with 3 volumes of 50:50 methanol/water (v/v) between each

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injection. Blank methanol was measured frequently and showed no signs of sample

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carryover with the exception of a few m/z peaks that always appeared in the blanks,

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which were attributed to the SPE resin and residues present in the methanol and the

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instrument. A sodium formate solution (10 mM) and a known homologous series of

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NOM were used to externally calibrate the instrument with a mass error of < 0.2 ppm

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and to internally recalibrate the mass spectra, respectively.

reproducibility

and

reliability

of

the

measurement.

To

minimize

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Bruker Daltonics data analysis software version 4.0 was used to identify and

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assign molecular formulas to the peaks with a signal-to-noise ratio (S/N) > 5. The

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molecular

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C1−50H0−100O0−40N0−3S0−2Br1-3 with the restrictions H/C < 2.2 and O/C < 1.2.42-44 The

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mass resolution was 4.5×105‒2.1×106 (for molecular weight between 200‒500 Da)

formulas

were

calculated

based

on

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and 3.2×105‒4.5×105 (for molecular weight between 500‒700 Da), and the mass error

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between the measured and calculated chemical formula was < 1 ppm. Because of the

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equal abundances of the 79Br and 81Br isotopes, the brominated compounds could be

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easily distinguished. Since FT-ICR MS has ultrahigh resolution for detecting Br-DBPs,

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the isotopic peaks for target compounds can be easily distinguished from adjacent

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peaks according to the isotopic simulation (Figure S2). Therefore, validation of the

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assigned Br-containing molecular formulas by isotope simulation was useful and

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reliable.36

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To visually display the distribution and components of these Br-DBPs, a van

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Krevelen diagram was constructed from the H/C and O/C ratios. The compounds

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were divided into five groups based on the modified aromaticity index (AI_mod) and

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the H/C ratio35 as follows: polycyclic aromatics (AI_mod > 0.66); polyphenols (0.5