| [1] |
United Nations Children’s Fund (UNICEF),World Health Organization (WHO). Progress on household drinking water, sanitation and hygiene 2000-2017: special focus on inequalities. Report. New York: UNICEF, WHO; 2019 Jun.
|
| [2] |
World Health Organization (WHO). Guidelines for drinking-water quality:fourth edition incorporating the first addendum. Report. Geneva: WHO; 2017.
|
| [3] |
K.N. Palansooriya, Y. Yang, Y.F. Tsang, B. Sarkar, D. Hou, X. Cao, et al.. Occurrence of contaminants in drinking water sources and the potential of biochar for water quality improvement: a review. Crit Rev Environ Sci Technol, 50 (6) ( 2020), pp. 549-611
|
| [4] |
I. Delpla, A.V. Jung, E. Baures, M. Clement, O. Thomas. Impacts of climate change on surface water quality in relation to drinking water production. Environ Int, 35 (8) ( 2009), pp. 1225-1233
|
| [5] |
A.K. Hohner, C.C. Rhoades, P. Wilkerson, F.L. Rosario-Ortiz. Wildfires alter forest watersheds and threaten drinking water quality. Acc Chem Res, 52 (5) ( 2019), pp. 1234-1244
|
| [6] |
J.P. Ritson, N.J.D. Graham, M.R. Templeton, J.M. Clark, R. Gough, C. Freeman. The impact of climate change on the treatability of dissolved organic matter (DOM) in upland water supplies: a UK perspective. Sci Total Environ, 473-474 ( 2014), pp. 714-730
|
| [7] |
H. Zhang, H. Li, D. Gao, H. Yu. Source identification of surface water pollution using multivariate statistics combined with physicochemical and socioeconomic parameters. Sci Total Environ, 806 (Pt 3) ( 2022), Article 151274
|
| [8] |
Y.C. Guo, S.W. Krasner. Occurrence of primidone, carbamazepine, caffeine, and precursors for N-nitrosodimethylamine in drinking water sources impacted by wastewater. J Am Water Resour Assoc, 45 (1) ( 2009), pp. 58-67
|
| [9] |
A. Daneshvar, K. Aboulfadl, L. Viglino, R. Broséus, S. Sauvé, A.S. Madoux-Humery, et al.. Evaluating pharmaceuticals and caffeine as indicators of fecal contamination in drinking water sources of the Greater Montreal region. Chemosphere, 88 (1) ( 2012), pp. 131-139
|
| [10] |
O. Hillebrand, K. Nödler, T. Licha, M. Sauter, T. Geyer. Caffeine as an indicator for the quantification of untreated wastewater in karst systems. Water Res, 46 (2) ( 2012), pp. 395-402
|
| [11] |
M. Wu, Y. Qian, J.M. Boyd, S.E. Hrudey, X.C. Le, X.F. Li. Direct large volume injection ultra-high performance liquid chromatography-tandem mass spectrometry determination of artificial sweeteners sucralose and acesulfame in well water. J Chromatogr A, 1359 ( 2014), pp. 156-161
|
| [12] |
S.D. Richardson, S.Y. Kimura. Emerging environmental contaminants: challenges facing our next generation and potential engineering solutions. Environ Technol Innovation, 8 ( 2017), pp. 40-56
|
| [13] |
S.D. Richardson, M.J. Plewa, E.D. Wagner, R. Schoeny, D.M. Demarini. Occurrence, genotoxicity, and carcinogenicity of regulated and emerging disinfection by-products in drinking water: a review and roadmap for research. Mutat Res, 636 (1-3) ( 2007), pp. 178-242
|
| [14] |
R. Xiao, T. Ou, S. Ding, C. Fang, Z. Xu, W. Chu. Disinfection by-products as environmental contaminants of emerging concern: a review on their occurrence, fate and removal in the urban water cycle. Crit Rev Environ Sci Technol, 53 (1) ( 2023), pp. 19-46
|
| [15] |
X.F. Li, W.A. Mitch. Drinking water disinfection byproducts (DBPs) and human health effects: multidisciplinary challenges and opportunities. Environ Sci Technol, 52 (4) ( 2018), pp. 1681-1689
|
| [16] |
T. Bond, M.R. Templeton, N. Graham. Precursors of nitrogenous disinfection by-products in drinking water—a critical review and analysis. J Hazard Mater, 235-236 ( 2012), pp. 1-16
|
| [17] |
M. Sgroi, F.G.A. Vagliasindi, S.A. Snyder, P. Roccaro. N-Nitrosodimethylamine (NDMA) and its precursors in water and wastewater: a review on formation and removal. Chemosphere, 191 ( 2018), pp. 685-703
|
| [18] |
M. Hou, W. Chu, F. Wang, Y. Deng, N. Gao, D. Zhang. The contribution of atmospheric particulate matter to the formation of CX3R-type disinfection by products in rainwater during chlorination. Water Res, 145 ( 2018), pp. 531-540
|
| [19] |
E. Aydin, F.B. Yaman, E. Ates Genceli, E. Topuz, E. Erdim, M. Gurel, et al.. Occurrence of THM and NDMA precursors in a watershed: effect of seasons and anthropogenic pollution. J Hazard Mater, 221-222 ( 2012), pp. 86-91
|
| [20] |
T.E.C. Kraus, B.A. Bergamaschi, P.J. Hernes, D. Doctor, C. Kendall, B.D. Downing, et al.. How reservoirs alter drinking water quality: organic matter sources, sinks, and transformations. Lake Reserv Manage, 27 (3) ( 2011), pp. 205-219
|
| [21] |
T.E.C. Kraus, C.A. Anderson, K. Morgenstern, B.D. Downing, B.A. Pellerin, B.A. Bergamaschi. Determining sources of dissolved organic carbon and disinfection byproduct precursors to the McKenzie River. Oregon J Environ Qual, 39 (6) ( 2010), pp. 2100-2112
|
| [22] |
J. Wei, B. Ye, W. Wang, L. Yang, J. Tao, Z. Hang. Spatial and temporal evaluations of disinfection by-products in drinking water distribution systems in Beijing, China. Sci Total Environ, 408 (20) ( 2010), pp. 4600-4606
|
| [23] |
H. Majidzadeh, H. Uzun, H. Chen, S. Bao, M.T.K. Tsui, T. Karanfil, et al.. Hurricane resulted in releasing more nitrogenous than carbonaceous disinfection byproduct precursors in coastal watersheds. Sci Total Environ, 705 ( 2020), Article 135785
|
| [24] |
K.M. Parker, T. Zeng, J. Harkness, A. Vengosh, W.A. Mitch. Enhanced formation of disinfection byproducts in shale gas wastewater-impacted drinking water supplies. Environ Sci Technol, 48 (19) ( 2014), pp. 11161-11169
|
| [25] |
W. Chen, Y. Chen, H. Huang, Y. Lu, M.S. Khorram, W. Zhao, et al.. Occurrence of N-nitrosamines in the Pearl River Delta of China: characterization and evaluation of different sources. Water Res, 164 ( 2019), Article 114896
|
| [26] |
B. Heng, R. Zhang, Z. Wang, Y. Zhang, Y. Wang, Z. Song, et al.. Occurrence and risk assessment of volatile halogenated disinfection by-products in an urban river supplied by reclaimed wastewater. Ecotoxicol Environ Saf, 211 ( 2021), Article 111912
|
| [27] |
J.J. Rook. Formation of haloforms during chlorination of natural waters. Water Treat Exam, 23 ( 1974), pp. 234-243
|
| [28] |
T.A. Bellar, J.J. Lichtenberg, R.C. Kroner. The occurrence of organohalides in chlorinated drinking waters. J Am Water Work Assoc, 66 (12) ( 1974), pp. 703-706
|
| [29] |
W.E. Coleman, R.D. Lingg, R.G. Melton, F.C. Kopfler. Keith ( Ed.),The occurrence of volatile organics in five drinking water supplies using GC/MS. L.H. Identification of analysis of organic pollutants in water, Science Publishers, Ann Arbor ( 1976), pp. 305-327
|
| [30] |
I.H. Suffet, L. Brenner, B. Silver. Identification of 1,1,1-trichloroacetone (1,1,1-trichloropropanone) in two drinking waters: a known precursor in haloform reaction. Environ Sci Technol, 10 (13) ( 1976), pp. 1273-1275
|
| [31] |
D.L. Norwood, J.D. Johnson, R.F. Christman, J.R. Hass, M.J. Bobenrieth. Reactions of chlorine with selected aromatic models of aquatic humic material. Environ Sci Technol, 14 (2) ( 1980), pp. 187-190
|
| [32] |
M.L. Trehy, T.I. Bieber. Keith ( Ed.),Detection, identification, and quantitative analysis of dihaloacetonitriles in chlorinated natural waters. L.H. Advances in the identification and analysis of organic pollutants in water, Science Publishers, Ann Arbor ( 1981), pp. 941-975
|
| [33] |
J.W. Miller, P.C. Uden. Characterization of non-volatile aqueous chlorination products of humic substances. Environ Sci Technol, 17 (3) ( 1983), pp. 150-157
|
| [34] |
T. Bond, J. Huang, M.R. Templeton, N. Graham. Occurrence and control of nitrogenous disinfection by-products in drinking water—a review. Water Res, 45 (15) ( 2011), pp. 4341-4354
|
| [35] |
K.S. Werdehoff, P.C. Singer. Chlorine dioxide effects on THMFP, TOXFP, and the formation of inorganic by-products. J Am Water Work Assoc, 79 (9) ( 1987), pp. 107-113
|
| [36] |
M. Bolyard, P.S. Fair, D.P. Hautman. Occurrence of chlorate in hypochlorite solutions used for drinking water disinfection. Environ Sci Technol, 26 (8) ( 1992), pp. 1663-1665
|
| [37] |
S.W. Krasner, H.S. Weinberg, S.D. Richardson, S.J. Pastor, R. Chinn, M.J. Sclimenti, et al.. Occurrence of a new generation of disinfection byproducts. Environ Sci Technol, 40 (23) ( 2006), pp. 7175-7185
|
| [38] |
Y. Zhao, F. Qin, J.M. Boyd, J. Anichina, X.F. Li. Characterization and determination of chloro- and bromo-benzoquinones as new chlorination disinfection byproducts in drinking water. Anal Chem, 82 (11) ( 2010), pp. 4599-4605
|
| [39] |
W. Chu, N. Gao, D. Yin, S.W. Krasner, M.R. Templeton. Trace determination of 13 haloacetamides in drinking water using liquid chromatography triple quadrupole mass spectrometry with atmospheric pressure chemical ionization. J Chromatogr A, 1235 ( 2012), pp. 178-181
|
| [40] |
Y. Pan, X. Zhang. Four groups of new aromatic halogenated disinfection byproducts: effect of bromide concentration on their formation and speciation in chlorinated drinking water. Environ Sci Technol, 47 (3) ( 2013), pp. 1265-1273
|
| [41] |
D. Zhang, W. Chu, Y. Yu, S.W. Krasner, Y. Pan, J. Shi, et al.. Occurrence and stability of chlorophenylacetonitriles: a new class of nitrogenous aromatic DBPs in chlorinated and chloraminated drinking waters. Environ Sci Technol Lett, 5 (6) ( 2018), pp. 394-399
|
| [42] |
B.G. Oliver. Dihaloacetonitriles in drinking water: algae and fulvic acid as precursors. Environ Sci Technol, 17 (2) ( 1983), pp. 80-83
|
| [43] |
B.G. Oliver, D.B. Shindler. Trihalomethanes from the chlorination of aquatic algae. Environ Sci Technol, 14 (12) ( 1980), pp. 1502-1505
|
| [44] |
M.L. Trehy, R.A. Yost, C.J. Miles. Chlorination byproducts of amino acids in natural waters. Environ Sci Technol, 20 (11) ( 1986), pp. 1117-1122
|
| [45] |
S. Ding, Y. Deng, T. Bond, C. Fang, Z. Cao, W. Chu. Disinfection byproduct formation during drinking water treatment and distribution: a review of unintended effects of engineering agents and materials. Water Res, 160 ( 2019), pp. 313-329
|
| [46] |
K.L. Rule, V.R. Ebbett, P.J. Vikesland. Formation of chloroform and chlorinated organics by free-chlorine-mediated oxidation of triclosan. Environ Sci Technol, 39 (9) ( 2005), pp. 3176-3185
|
| [47] |
P. Canosa, I. Rodriguez, E. Rubi, N. Negreira, R. Cela. Formation of halogenated by-products of parabens in chlorinated water. Anal Chim Acta, 575 (1) ( 2006), pp. 106-113
|
| [48] |
W.H. Chen, T.M. Young. NDMA formation during chlorination and chloramination of aqueous diuron solutions. Environ Sci Technol, 42 (4) ( 2008), pp. 1072-1077
|
| [49] |
M. Oya, K. Kosaka, M. Asami, S. Kunikane. Formation of N-nitrosodimethylamine (NDMA) by ozonation of dyes and related compounds. Chemosphere, 73 (11) ( 2008), pp. 1724-1730
|
| [50] |
B. Chen, S.N. Nam, P.K. Westerhoff, S.W. Krasner, G. Amy. Fate of effluent organic matter and DBP precursors in an effluent-dominated river: a case study of wastewater impact on downstream water quality. Water Res, 43 (6) ( 2009), pp. 1755-1765
|
| [51] |
S.E. Duirk, C. Lindell, C.C. Cornelison, J. Kormos, T.A. Ternes, M. Attene-Ramos, et al.. Formation of toxic iodinated disinfection by-products from compounds used in medical imaging. Environ Sci Technol, 45 (16) ( 2011), pp. 6845-6854
|
| [52] |
R. Shen, S.A. Andrews. Demonstration of 20 pharmaceuticals and personal care products (PPCPs) as nitrosamine precursors during chloramine disinfection. Water Res, 45 (2) ( 2011), pp. 944-952
|
| [53] |
W.H. Chu, S.W. Krasner, N.Y. Gao, M.R. Templeton, D.Q. Yin. Contribution of the antibiotic chloramphenicol and its analogues as precursors of dichloroacetamide and other disinfection byproducts in drinking water. Environ Sci Technol, 50 (1) ( 2016), pp. 388-396
|
| [54] |
K. Watson, G. Shaw, F.D.L. Leusch, N.L. Knight. Chlorine disinfection by-products in wastewater effluent: bioassay-based assessment of toxicological impact. Water Res, 46 (18) ( 2012), pp. 6069-6083
|
| [55] |
Y. Luo, L. Feng, Y. Liu, L. Zhang. Disinfection by-products formation and acute toxicity variation of hospital wastewater under different disinfection processes. Separ Purif Tech, 238 ( 2020), Article 116405
|
| [56] |
M.L. Hladik, M.J. Focazio, M. Engle. Discharges of produced waters from oil and gas extraction via wastewater treatment plants are sources of disinfection by-products to receiving streams. Sci Total Environ, 466-467 ( 2014), pp. 1085-1093
|
| [57] |
Y.H. Chuang, F. Shabani, J. Munoz, R. Aflaki, S.D. Hammond, W.A. Mitch. Comparing industrial and domestic discharges as sources of N-nitrosamines and their chloramine or ozone-reactive precursors. Environ Sci Water Res Technol, 5 (4) ( 2019), pp. 726-736
|
| [58] |
D. Kim, G.L. Amy, T. Karanfil. Disinfection by-product formation during seawater desalination: a review. Water Res, 81 ( 2015), pp. 343-355
|
| [59] |
S. Ding, W. Chu, T. Bond, Q. Wang, N. Gao, B. Xu, et al.. Formation and estimated toxicity of trihalomethanes, haloacetonitriles, and haloacetamides from the chlor(am)ination of acetaminophen. J Hazard Mater, 341 ( 2018), pp. 112-119
|
| [60] |
Z. Li, X. Liu, Z. Huang, S. Hu, J. Wang, Z. Qian, et al.. Occurrence and ecological risk assessment of disinfection byproducts from chlorination of wastewater effluents in east China. Water Res, 157 ( 2019), pp. 247-257
|
| [61] |
M. David, J. Linders, S. Gollasch, J. David. Is the aquatic environment sufficiently protected from chemicals discharged with treated ballast water from vessels worldwide?—A decadal environmental perspective and risk assessment. Chemosphere, 207 ( 2018), pp. 590-600
|
| [62] |
H. Cui, B. Chen, Y. Jiang, Y. Tao, X. Zhu, Z. Cai. Toxicity of 17 disinfection by-products to different trophic levels of aquatic organisms: ecological risks and mechanisms. Environ Sci Technol, 55 (15) ( 2021), pp. 10534-10541
|
| [63] |
X. Luan, X. Liu, C. Fang, W. Chu, Z. Xu. Ecotoxicological effects of disinfected wastewater effluents: a short review of in vivo toxicity bioassays on aquatic organisms. Environ Sci Water Res Technol, 6 (9) ( 2020), pp. 2275-2286
|
| [64] |
J. Liu, X. Zhang. Comparative toxicity of new halophenolic DBPs in chlorinated saline wastewater effluents against a marine alga: halophenolic DBPs are generally more toxic than haloaliphatic ones. Water Res, 65 ( 2014), pp. 64-72
|
| [65] |
M. Grote, J.L. Boudenne, J.P. Croué, B.I. Escher, U. von Gunten, J. Hahn, et al.. Inputs of disinfection by-products to the marine environment from various industrial activities: comparison to natural production. Water Res, 217 ( 2022), Article 118383
|
| [66] |
S.W. Krasner, P. Westerhoff, B. Chen, B.E. Rittmann, G. Amy. Occurrence of disinfection byproducts in United States wastewater treatment plant effluents. Environ Sci Technol, 43 (21) ( 2009), pp. 8320-8325
|
| [67] |
G. Ding, X. Zhang, M. Yang, Y. Pan. Formation of new brominated disinfection byproducts during chlorination of saline sewage effluents. Water Res, 47 (8) ( 2013), pp. 2710-2718
|
| [68] |
X. Yang, C. Shang, J.C. Huang. DPB formation in breakpoint chlorination of wastewater. Water Res, 39 (19) ( 2005), pp. 4755-4767
|
| [69] |
A.F. Gilca, C. Teodosiu, S. Fiore, C.P. Musteret. Emerging disinfection byproducts: a review on their occurrence and control in drinking water treatment processes. Chemosphere, 259 ( 2020), Article 127476
|
| [70] |
G. Hua, D.A. Reckhow. Comparison of disinfection byproduct formation from chlorine and alternative disinfectants. Water Res, 41 (8) ( 2007), pp. 1667-1678
|
| [71] |
L.C. Hua, C.H. Lai, G.S. Wang, T.F. Lin, C. Huang. Algogenic organic matter derived DBPs: precursor characterization, formation, and future perspectives—a review. Crit Rev Environ Sci Technol, 49 (19) ( 2019), pp. 1803-1834
|
| [72] |
T. Bond, E.H. Goslan, S.A. Parsons, B. Jefferson. A critical review of trihalomethane and haloacetic acid formation from natural organic matter surrogates. Environ Technol Rev, 1 (1) ( 2012), pp. 93-113
|
| [73] |
H. MacKeown, U. von Gunten, J. Criquet. Iodide sources in the aquatic environment and its fate during oxidative water treatment—a critical review. Water Res, 217 ( 2022), Article 118417
|
| [74] |
M.B. Heeb, J. Criquet, S.G. Zimmermann-Steffens, U. von Gunten. Oxidative treatment of bromide-containing waters: formation of bromine and its reactions with inorganic and organic compounds—a critical review. Water Res, 48 ( 2014), pp. 15-42
|
| [75] |
S.W. Krasner. The formation and control of emerging disinfection by-products of health concern. Philos Trans R Soc A Math Phys Eng, 367 ( 1904) ( 2009), pp. 4077-4095
|
| [76] |
H. Dong, Z. Qiang, S.D. Richardson. Formation of iodinated disinfection byproducts (I-DBPs) in drinking water: emerging concerns and current issues. Acc Chem Res, 52 (4) ( 2019), pp. 896-905
|
| [77] |
K. Watson, M.J. Farré, N. Knight. Strategies for the removal of halides from drinking water sources, and their applicability in disinfection by-product minimisation: a critical review. J Environ Manage, 110 ( 2012), pp. 276-298
|
| [78] |
A. Vengosh, R.B. Jackson, N. Warner, T.H. Darrah, A. Kondash. A critical review of the risks to water resources from unconventional shale gas development and hydraulic fracturing in the United States. Environ Sci Technol, 48 (15) ( 2014), pp. 8334-8348
|
| [79] |
G. Hua, D.A. Reckhow, J. Kim. Effect of bromide and iodide ions on the formation and speciation of disinfection byproducts during chlorination. Environ Sci Technol, 40 (9) ( 2006), pp. 3050-3056
|
| [80] |
W.H. Chu, N.Y. Gao, Y. Deng, S.W. Krasner. Precursors of dichloroacetamide, an emerging nitrogenous DBP formed during chlorination or chloramination. Environ Sci Technol, 44 (10) ( 2010), pp. 3908-3912
|
| [81] |
A.D. Shah, W.A. Mitch. Halonitroalkanes, halonitriles, haloamides, and N-nitrosamines: a critical review of nitrogenous disinfection byproduct formation pathways. Environ Sci Technol, 46 (1) ( 2012), pp. 119-131
|
| [82] |
H.K. Shon, S. Vigneswaran, S.A. Snyder. Effluent organic matter (EfOM) in wastewater: constituents, effects, and treatment. Crit Rev Environ Sci Technol, 36 (4) ( 2006), pp. 327-374
|
| [83] |
W. Beita-Sandí, C.U. Erdem, T. Karanfil. Effect of bromide on NDMA formation during chloramination of model precursor compounds and natural waters. Water Res, 170 ( 2020), Article 115323
|
| [84] |
Y. Bichsel, U. von Gunten. Formation of iodo-trihalomethanes during disinfection and oxidation of iodide-containing waters. Environ Sci Technol, 34 (13) ( 2000), pp. 2784-2791
|
| [85] |
A. Tomlinson, M. Drikas, J.D. Brookes. The role of phytoplankton as pre-cursors for disinfection by-product formation upon chlorination. Water Res, 102 ( 2016), pp. 229-240
|
| [86] |
T. Zeng, C.M. Glover, E.J. Marti, G.C. Woods-Chabane, T. Karanfil, W.A. Mitch, et al.. Relative importance of different water categories as sources of N-nitrosamine precursors. Environ Sci Technol, 50 (24) ( 2016), pp. 13239-13248
|
| [87] |
C. Liu, M.S. Ersan, M.J. Plewa, G. Amy, T. Karanfil. Formation of iodinated trihalomethanes and noniodinated disinfection byproducts during chloramination of algal organic matter extracted from Microcystis aeruginosa. Water Res, 162 ( 2019), pp. 115-126
|
| [88] |
World Health Organization (WHO). Pharmaceuticals in drinking-water. Report. Geneva: WHO; 2012.
|
| [89] |
D. Hanigan, E.M. Thurman, I. Ferrer, Y. Zhao, S. Andrews, J. Zhang, et al.. Methadone contributes to N-nitrosodimethylamine formation in surface waters and wastewaters during chloramination. Environ Sci Technol Lett, 2 (6) ( 2015), pp. 151-157
|
| [90] |
C.K. Schmidt, H.J.N. Brauch. N,N-Dimethylsulfamide as precursor for N-nitrosodimethylamine (NDMA) formation upon ozonation and its fate during drinking water treatment. Environ Sci Technol, 42 (17) ( 2008), pp. 6340-6346
|
| [91] |
K. Kosaka, M. Asami, K. Ohkubo, T. Iwamoto, Y. Tanaka, H. Koshino, et al.. Identification of a new N-nitrosodimethylamine precursor in sewage containing industrial effluents. Environ Sci Technol, 48 (19) ( 2014), pp. 11243-11250
|
| [92] |
J.E. Bell, C.L. Brown, K. Conlon, S. Herring, K.E. Kunkel, J. Lawrimore, et al.. Changes in extreme events and the potential impacts on human health. J Air Waste Manag Assoc, 68 (4) ( 2018), pp. 265-287
|
| [93] |
J.M. O’Neil, T.W. Davis, M.A. Burford, C.J. Gobler. The rise of harmful cyanobacteria blooms: the potential roles of eutrophication and climate change. Harmful Algae, 14 ( 2012), pp. 313-334
|
| [94] |
A.D. Werner, M. Bakker, V.E.A. Post, A. Vandenbohede, C. Lu, B. Ataie-Ashtiani, et al.. Seawater intrusion processes, investigation and management: recent advances and future challenges. Adv Water Resour, 51 ( 2013), pp. 3-26
|
| [95] |
K.D. Bladon, M.B. Emelko, U. Silins, M. Stone. Wildfire and the future of water supply. Environ Sci Technol, 48 (16) ( 2014), pp. 8936-8943
|
| [96] |
Federal-Provincial-Territorial Committee on Drinking Water (CDW), Canadian Council of Ministers of the Environment (CCME). From source to tap:guidance on the multi-barrier approach to safe drinking water. Report. Manitoba: CDW, CCME; 2004.
|
| [97] |
S.Y. Wee, A.Z. Aris. Endocrine disrupting compounds in drinking water supply system and human health risk implication. Environ Int, 106 ( 2017), pp. 207-233
|
| [98] |
C.B. Andersen, G.P. Lewis, K.A. Sargent. Influence of wastewater-treatment effluent on concentrations and fluxes of solutes in the Bush River, South Carolina, during extreme drought conditions. Environ Geosci, 11 (1) ( 2004), pp. 28-41
|
| [99] |
M.Y. Cheung, S. Liang, J. Lee. Toxin-producing cyanobacteria in freshwater: a review of the problems, impact on drinking water safety, and efforts for protecting public health. J Microbiol, 51 (1) ( 2013), pp. 1-10
|
| [100] |
E. Bei, X. Liao, X. Meng, S. Li, J. Wang, D. Sheng, et al.. Identification of nitrosamine precursors from urban drainage during storm events: a case study in southern China. Chemosphere, 160 ( 2016), pp. 323-331
|
| [101] |
H. Majidzadeh, H. Uzun, A. Ruecker, D. Miller, J. Vernon, H. Zhang, et al.. Extreme flooding mobilized dissolved organic matter from coastal forested wetlands. Biogeochemistry, 136 (3) ( 2017), pp. 293-309
|
| [102] |
B. Zhao, Y. Wong, M. Ihara, N. Nakada, Z. Yu, Y. Sugie, et al.. Characterization of nitrosamines and nitrosamine precursors as non-point source pollutants during heavy rainfall events in an urban water environment. J Hazard Mater, 424 (Pt C) ( 2022), Article 127552
|
| [103] |
I. Delpla, T.G. Jones, D.T. Monteith, D.D. Hughes, E. Baurès, A.V. Jung, et al.. Heavy rainfall impacts on trihalomethane formation in contrasting northwestern European potable waters. J Environ Qual, 44 (4) ( 2015), pp. 1241-1251
|
| [104] |
A. Ruecker, H. Uzun, T. Karanfil, M.T.K. Tsui, A.T. Chow. Disinfection byproduct precursor dynamics and water treatability during an extreme flooding event in a coastal blackwater river in southeastern United States. Chemosphere, 188 ( 2017), pp. 90-98
|
| [105] |
H.V.M. Nguyen, M.H. Lee, J. Hur, M.A. Schlautman. Variations in spectroscopic characteristics and disinfection byproduct formation potentials of dissolved organic matter for two contrasting storm events. J Hydrol, 481 ( 2013), pp. 132-142
|
| [106] |
I. Delpla, M.J. Rodriguez. Experimental disinfection by-product formation potential following rainfall events. Water Res, 104 ( 2016), pp. 340-348
|
| [107] |
C.J. Chang, C.P. Huang, C.Y. Chen, G.S. Wang. Assessing the potential effect of extreme weather on water quality and disinfection by-product formation using laboratory simulation. Water Res, 170 ( 2020), Article 115296
|
| [108] |
E.C. Ged, T.H. Boyer. Effect of seawater intrusion on formation of bromine-containing trihalomethanes and haloacetic acids during chlorination. Desalination, 345 ( 2014), pp. 85-93
|
| [109] |
C. Kolb, M. Pozzi, C. Samaras, J.M. VanBriesen.Climate change impacts on bromide, trihalomethane formation, and health risks at coastal groundwater utilities. ASCE ASME J Risk U A, 3 (3) ( 2017), p. 04017006
|
| [110] |
C.D. Wu, C.X. Hu, J.Y. Zhang, B. Hu, L. Wang, J.L. Liang. Survey of seawater intrusion in the Pearl River Basin and modeling bromate formation during ozonation of the raw water. Ozone Sci Eng, 35 (6) ( 2013), pp. 465-471
|
| [111] |
S.W. Krasner, M.J. Sclimenti, E.G. Means. Quality degradation: implications for DBP formation. J Am Water Works Assoc, 86 (6) ( 1994), pp. 34-47
|
| [112] |
T.R. Young, S. Deem, J.C. Leslie, V. Salo-Zieman, H. He, M.C. Dodd. Drivers of disinfection byproduct formation and speciation in small, chlorinated coastal groundwater systems: relative roles of bromide and organic matter, and the need for improved source water characterization and monitoring. Environ Sci Water Res Technol, 6 (12) ( 2020), pp. 3361-3379
|
| [113] |
A.T. Chow, K.P. Tsai, T.S. Fegel, D.N. Pierson, C.C. Rhoades. Lasting effects of wildfire on disinfection by-product formation in forest catchments. J Environ Qual, 48 (6) ( 2019), pp. 1826-1834
|
| [114] |
H. Uzun, R.A. Dahlgren, C. Olivares, C.U. Erdem, T. Karanfil, A.T. Chow. Two years of post-wildfire impacts on dissolved organic matter, nitrogen, and precursors of disinfection by-products in California stream waters. Water Res, 181 ( 2020), Article 115891
|
| [115] |
A.K. Hohner, K. Cawley, J. Oropeza, R.S. Summers, F.L. Rosario-Ortiz. Drinking water treatment response following a Colorado wildfire. Water Res, 105 ( 2016), pp. 187-198
|
| [116] |
J.J. Wang, R.A. Dahlgren, M.S. Erşan, T. Karanfil, A.T. Chow. Wildfire altering terrestrial precursors of disinfection byproducts in forest detritus. Environ Sci Technol, 49 (10) ( 2015), pp. 5921-5929
|
| [117] |
A.K. Hohner, L.G. Terry, E.B. Townsend, R.S. Summers, F.L. Rosario-Ortiz. Water treatment process evaluation of wildfire-affected sediment leachates. Environ Sci Water Res Technol, 3 (2) ( 2017), pp. 352-365
|
| [118] |
W. Chu, D. Yao, Y. Deng, M. Sui, N. Gao. Production of trihalomethanes, haloacetaldehydes and haloacetonitriles during chlorination of microcystin-LR and impacts of pre-oxidation on their formation. J Hazard Mater, 327 ( 2017), pp. 153-160
|
| [119] |
L. Li, N. Gao, Y. Deng, J. Yao, K. Zhang. Characterization of intracellular and extracellular algae organic matters (AOM) of Microcystic aeruginosa and formation of AOM-associated disinfection byproducts and odor and taste compounds. Water Res, 46 (4) ( 2012), pp. 1233-1240
|
| [120] |
J. Fang, X. Yang, J. Ma, C. Shang, Q. Zhao. Characterization of algal organic matter and formation of DBPs from chlor(am)ination. Water Res, 44 (20) ( 2010), pp. 5897-5906
|
| [121] |
M. Pivokonsky, J. Naceradska, I. Kopecka, M. Baresova, B. Jefferson, X. Li, et al.. The impact of algogenic organic matter on water treatment plant operation and water quality: a review. Crit Rev Environ Sci Technol, 46 (4) ( 2016), pp. 291-335
|
| [122] |
M.L. Nguyen, P. Westerhoff, L. Baker, Q. Hu, M. Esparza-Soto, M. Sommerfeld. Characteristics and reactivity of algae-produced dissolved organic carbon. J Environ Eng, 131 (11) ( 2005), pp. 1574-1582
|
| [123] |
K. Foreman, D. Vacs Renwick, M. McCabe, A. Cadwallader, H. Holsinger, C. Kormondy, et al.. Effects of harmful algal blooms on regulated disinfection byproducts: findings from five utility case studies. AWWA Water Sci, 3 (3) ( 2021), p. e1223
|
| [124] |
K.P. Tsai, H. Uzun, H. Chen, T. Karanfil, A.T. Chow. Control wildfire-induced Microcystis aeruginosa blooms by copper sulfate: trade-offs between reducing algal organic matter and promoting disinfection byproduct formation. Water Res, 158 ( 2019), pp. 227-236
|
| [125] |
K.P. Tsai, A.T. Chow. Growing algae alter spectroscopic characteristics and chlorine reactivity of dissolved organic matter from thermally-altered forest litters. Environ Sci Technol, 50 (15) ( 2016), pp. 7991-8000
|
| [126] |
Y.C. Soh, F. Roddick, J. van Leeuwen. The future of water in Australia: the potential effects of climate change and ozone depletion on Australian water quality, quantity and treatability. Environmentalist, 28 (2) ( 2008), pp. 158-165
|
| [127] |
M.H. Lee, J. Hur. Photodegradation-induced changes in the characteristics of dissolved organic matter with different sources and their effects on disinfection by-product formation potential. Clean, 42 (5) ( 2014), pp. 552-560
|
| [128] |
A.T. Chow, D.M. Leech, T.H. Boyer, P.C. Singer. Impact of simulated solar irradiation on disinfection byproduct precursors. Environ Sci Technol, 42 (15) ( 2008), pp. 5586-5593
|
| [129] |
A.T. Chow, F.J. Díaz, K.H. Wong, A.T. O’Geen, R.A. Dahlgren, P.K. Wong. Photochemical and bacterial transformations of disinfection by-product precursors in water. J Environ Qual, 42 (5) ( 2013), pp. 1589-1595
|
| [130] |
J. Wu, J. Ye, H. Peng, M. Wu, W. Shi, Y. Liang, et al.. Solar photolysis of soluble microbial products as precursors of disinfection by-products in surface water. Chemosphere, 201 ( 2018), pp. 66-76
|
| [131] |
J. Xu, Z.T. Kralles, C.H. Hart, N. Dai. Effects of sunlight on the formation potential of dichloroacetonitrile and bromochloroacetonitrile from wastewater effluents. Environ Sci Technol, 54 (6) ( 2020), pp. 3245-3255
|
| [132] |
J. Xu, Z.T. Kralles, N. Dai. Effects of sunlight on the trichloronitromethane formation potential of wastewater effluents: dependence on nitrite concentration. Environ Sci Technol, 53 (8) ( 2019), pp. 4285-4294
|
| [133] |
H.S. Lee, J. Hur, H.S. Shin. Dynamic exchange between particulate and dissolved matter following sequential resuspension of particles from an urban watershed under photo-irradiation. Environ Pollut, 283 ( 2021), Article 117395
|
| [134] |
H.S. Lee, J. Hur, M.H. Lee, S.R. Brogi, T.W. Kim, H.S. Shin. Photochemical release of dissolved organic matter from particulate organic matter: spectroscopic characteristics and disinfection by-product formation potential. Chemosphere, 235 ( 2019), pp. 586-595
|
| [135] |
M.C. Hsieh, W.W.P. Lai, A.Y.C. Lin. Sunlight photolysis mitigates the formation of N-nitrosodimethylamine (NDMA) during the chloramination of methadone. Chem Eng J, 384 ( 2020), Article 123307
|
| [136] |
L. Ritter, K. Solomon, P. Sibley, K. Hall, P. Keen, G. Mattu, et al.. Sources, pathways, and relative risks of contaminants in surface water and groundwater: a perspective prepared for the Walkerton inquiry. J Toxicol Environ Health A, 65 (1) ( 2002), pp. 1-142
|
| [137] |
J.H. Seinfeld, J.F. Pankow. Organic atmospheric particulate material. Annu Rev Phys Chem, 54 (1) ( 2003), pp. 121-140
|
| [138] |
M. Shi, B. Geng, T. Zhao, F. Wang. Influence of atmospheric deposition on surface water quality and DBP formation potential as well as control technology of rainwater DBPs: a review. Environ Sci Water Res Technol, 7 (12) ( 2021), pp. 2156-2165
|
| [139] |
J. He, F. Wang, T. Zhao, S. Liu, W. Chu. Characterization of dissolved organic matter derived from atmospheric dry deposition and its DBP formation. Water Res, 171 ( 2020), Article 115368
|
| [140] |
J. He, M. Shi, F. Wang, Y. Duan, T. Zhao, S. Shu, et al.. Removal of CX3R-type disinfection by-product precursors from rainwater with conventional drinking water treatment processes. Water Res, 185 ( 2020), Article 116099
|
| [141] |
T. Zeng, W.A. Mitch. Contribution of N-nitrosamines and their precursors to domestic sewage by greywaters and blackwaters. Environ Sci Technol, 49 (22) ( 2015), pp. 13158-13167
|
| [142] |
Z. Xu, J. Xu, H. Yin, W. Jin, H. Li, Z. He. Urban river pollution control in developing countries. Nat Sustain, 2 (3) ( 2019), pp. 158-160
|
| [143] |
L. Peng, F. Wang, D. Zhang, C. Fang, J.P. van der Hoek, W. Chu. Effect of oxidation ditch and anaerobic-anoxic-oxic processes on CX3R-type disinfection by-product formation during wastewater treatment. Sci Total Environ, 770 ( 2021), Article 145344
|
| [144] |
S.W. Krasner, P. Westerhoff, B. Chen, B.E. Rittmann, S.N. Nam, G. Amy. Impact of wastewater treatment processes on organic carbon, organic nitrogen, and DBP precursors in effuent organic matter. Environ Sci Technol, 43 (8) ( 2009), pp. 2911-2918
|
| [145] |
A. Dotson, P. Westerhoff, S.W. Krasner. Nitrogen enriched dissolved organic matter (DOM) isolates and their affinity to form emerging disinfection by-products. Water Sci Technol, 60 (1) ( 2009), pp. 135-143
|
| [146] |
T.F. Marhaba, A. Mangmeechai, C. Chaiwatpongsakorn, P. Pavasant. Trihalomethanes formation potential of shrimp farm effluents. J Hazard Mater, 136 (2) ( 2006), pp. 151-163
|
| [147] |
S.L. Leavey-Roback, S.W. Krasner, I.M. Suffet. Veterinary antibiotics used in animal agriculture as NDMA precursors. Chemosphere, 164 ( 2016), pp. 330-338
|
| [148] |
C.Y. Hu, Y.G. Deng, Y.L. Lin, Y.Z. Hou. Chlorination of bromacil: kinetics and disinfection by-products. Separ Purif Tech, 212 ( 2019), pp. 913-919
|
| [149] |
R.S. Eckard, B.A. Bergamaschi, B.A. Pellerin, T. Kraus, P.J. Hernes. Trihalomethane precursors: land use hot spots, persistence during transport, and management options. Sci Total Environ, 742 ( 2020), Article 140571
|
| [150] |
Y. Qiu, E. Bei, X. Li, S. Xie, H. Xiao, Y. Luo, et al.. Quantitative analysis of source and fate of N-nitrosamines and their precursors in an urban water system in east China. J Hazard Mater, 415 ( 2021), Article 125700
|
| [151] |
S. States, G. Cyprych, M. Stoner, F. Wydra, J. Kuchta, J. Monnell, et al.. Marcellus shale drilling and brominated THMs in Pittsburgh, Pa., drinking water. J Am Water Works Assoc, 105 (8) ( 2013), pp. E432-E448
|
| [152] |
N.E. McTigue, D.A. Cornwell, K. Graf, R. Brown. Occurrence and consequences of increased bromide in drinking water sources. J Am Water Works Assoc, 106 (11) ( 2014), pp. E492-E508
|
| [153] |
A.M.A. Simpson, W.A. Mitch. Chlorine and ozone disinfection and disinfection byproducts in postharvest food processing facilities: a review. Crit Rev Environ Sci Technol, 52 (11) ( 2022), pp. 1825-1867
|
| [154] |
M.L. Hladik, L.E. Hubbard, D.W. Kolpin, M.J. Focazio. Dairy-impacted wastewater is a source of iodinated disinfection byproducts in the environment. Environ Sci Technol Lett, 3 (5) ( 2016), pp. 190-193
|
| [155] |
C. Lin, X. Zhuo, X. Yu, M. Yuan, C. Wei. Identification of disinfection by-product precursors from the discharge of a coking wastewater treatment plant. RSC Adv, 5 (54) ( 2015), pp. 43786-43797
|
| [156] |
K.D. Good, J.M. VanBriesen. Current and potential future bromide loads from coal-fired power plants in the Allegheny River Basin and their effects on downstream concentrations. Environ Sci Technol, 50 (17) ( 2016), pp. 9078-9088
|
| [157] |
K.D. Good, J.M. VanBriesen. Power plant bromide discharges and downstream drinking water systems in Pennsylvania. Environ Sci Technol, 51 (20) ( 2017), pp. 11829-11838
|
| [158] |
C. Kolb, K.D. Good, J.M. VanBriesen. Modeling trihalomethane increases associated with source water bromide contributed by coal-fired power plants in the Monongahela River Basin. Environ Sci Technol, 54 (2) ( 2020), pp. 726-734
|
| [159] |
J.M. VanBriesen, A.T. Carpenter, K.D. Good, C. Kolb, J.M. Wilson. Power plant bromide discharges and potential effects on DBP formation. J Am Water Works Assoc, 113 (6) ( 2021), pp. 48-55
|
| [160] |
N.R. Warner, C.A. Christie, R.B. Jackson, A. Vengosh. Impacts of shale gas wastewater disposal on water quality in western Pennsylvania. Environ Sci Technol, 47 (20) ( 2013), pp. 11849-11857
|
| [161] |
K.J. Ferrar, D.R. Michanowicz, C.L. Christen, N. Mulcahy, S.L. Malone, R.K. Sharma. Assessment of effluent contaminants from three facilities discharging Marcellus Shale wastewater to surface waters in Pennsylvania. Environ Sci Technol, 47 (7) ( 2013), pp. 3472-3481
|
| [162] |
M.S. Landis, A.S. Kamal, K.D. Kovalcik, C. Croghan, G.A. Norris, A. Bergdale. The impact of commercially treated oil and gas produced water discharges on bromide concentrations and modeled brominated trihalomethane disinfection byproducts at two downstream municipal drinking water plants in the upper Allegheny River, Pennsylvania, USA. Sci Total Environ, 542 (Pt A) ( 2016), pp. 505-520
|
| [163] |
K.Z. Huang, Y.F. Xie, H.L. Tang. Formation of disinfection by-products under influence of shale gas produced water. Sci Total Environ, 647 ( 2019), pp. 744-751
|
| [164] |
J.S. Harkness, G.S. Dwyer, N.R. Warner, K.M. Parker, W.A. Mitch, A. Vengosh. Iodide, bromide, and ammonium in hydraulic fracturing and oil and gas wastewaters: environmental implications. Environ Sci Technol, 49 (3) ( 2015), pp. 1955-1963
|
| [165] |
K.Z. Huang, H.L. Tang, Y.F. Xie. Impacts of shale gas production wastewater on disinfection byproduct formation: an investigation from a non-bromide perspective. Water Res, 144 ( 2018), pp. 656-664
|
| [166] |
S.W. Krasner, W.A. Mitch, P. Westerhoff, A. Dotson. Formation and control of emerging C- and N-DBPs in drinking water. J Am Water Works Assoc, 104 (11) ( 2012), pp. E582-E595
|
| [167] |
S.W. Krasner, W.A. Mitch, D.L. McCurry, D. Hanigan,P. Westerhoff. Formation, precursors, control, and occurrence of nitrosamines in drinking water: a review. Water Res, 47 (13) ( 2013), pp. 4433-4450
|
| [168] |
Z. Li, G. Song, Y. Bi, W. Gao, A. He, Y. Lu, et al.. Occurrence and distribution of disinfection byproducts in domestic wastewater effluent, tap water, and surface water during the SARS-CoV-2 pandemic in China. Environ Sci Technol, 55 (7) ( 2021), pp. 4103-4114
|
| [169] |
E. Emmanuel, Y. Perrodin, G. Keck, J.M. Blanchard, P. Vermande. Ecotoxicological risk assessment of hospital wastewater: a proposed framework for raw effluents discharging into urban sewer network. J Hazard Mater, 117 (1) ( 2005), pp. 1-11
|
| [170] |
A. Matilainen, E.T. Gjessing, T. Lahtinen, L. Hed, A. Bhatnagar, M. Sillanpää. An overview of the methods used in the characterisation of natural organic matter (NOM) in relation to drinking water treatment. Chemosphere, 83 (11) ( 2011), pp. 1431-1442
|
| [171] |
Y. Pan, H. Li, X. Zhang, A. Li. Characterization of natural organic matter in drinking water: sample preparation and analytical approaches. Trends Environ Anal Chem, 12 ( 2016), pp. 23-30
|
| [172] |
C. Fang, X. Yang, S. Ding, X. Luan, R. Xiao, Z. Du, et al.. Characterization of dissolved organic matter and its derived disinfection byproduct formation along the Yangtze River. Environ Sci Technol, 55 (18) ( 2021), pp. 12326-12336
|
| [173] |
L.T. Leonard, G.F. Vanzin, V.A. Garayburu-Caruso, S.S. Lau, C.A. Beutler, A.W. Newman, et al.. Disinfection byproducts formed during drinking water treatment reveal an export control point for dissolved organic matter in a subalpine headwater stream. Water Res X, 15 ( 2022), Article 100144
|
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