The Journal of
the Korean Society on Water Environment

The Journal of
the Korean Society on Water Environment

Bimonthly
  • ISSN : 2289-0971 (Print)
  • ISSN : 2289-098X (Online)
  • KCI Accredited Journal

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  3. 2026-01 (Vol. 42, No. 1)
  4. 10.15681/KSWE.2026.42.1.14
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References

1 
An S., Yoon Y., Ahn J. H., Kim D., Weon H. Y., Kim Y. E., Hur H. G., Yang Y., 2023, Oxidative degradation of bisphenol A by Bio-Fenton reaction equipped with glucose oxidase and ferric citrate: Degradation kinetics and pathway, Journal of Environmental Chemical Engineering, Vol. 11, No. 2, pp. 109349DOI
2 
Bielski B. H., Thomas M., 1987, Studies of hypervalent iron in aqueous solutions. 1. Radiation-induced reduction of iron (VI) to iron (V) by CO₂-, Journal of the American Chemical Society, Vol. 109, pp. 7761-7764DOI
3 
Chen Z., Li C., Su J., He Z., Xu J., Bian Y., Kim H., Guan X., 2025, Enhanced sulfamethoxazole removal in water and wastewater by ferrate(VI)/perborate system via borate buffering, Journal of Hazardous Materials, Vol. 483, pp. 138261DOI
4 
Chung K. T., 2016, Azo dyes and human health: A review, Journal of Environmental Science and Health, Part C: Environmental Carcinogenesis & Ecotoxicology Reviews, Vol. 34, No. 4, pp. 233-261DOI
5 
del Olmo A., Calzada J., Nuñez M., 2015, Benzoic acid and its derivatives as naturally occurring compounds in foods and as additives: Uses, exposure, and controversy, Critical Reviews in Food Science and Nutrition, Vol. 57, No. 14, pp. 3084-3103DOI
6 
Deng Y., Guan X., 2024, Unlocking the potential of ferrate (VI) in water treatment: Toward one-step multifunctional solutions, Journal of Hazardous Materials, Vol. 464, pp. 132920DOI
7 
Fan M., Zhou Y., Luo J., Gao Y., Qiu J., Yang X., 2025, Formation of highly toxic halogenated coupling byproducts in UV/Chlorine reaction of phenols in presence of halides, Water Research, Vol. 246, pp. 121178DOI
8 
Fu S. F., Chi W. C., Chen Y. A., Hsiung Y. C., Chou C. H., Yeh K. W., 2013, Autotoxicity mechanism of Oryza sativa: Transcriptome response in rice roots exposed to ferulic acid, BMC Genomics, Vol. 14, pp. 351DOI
9 
He T., Zhou B., Chen H., Yuan R., 2022, Degradation of organic chemicals in aqueous system through ferrate-based processes: A review, Journal of Environmental Chemical Engineering, Vol. 10, No. 6, pp. 108706DOI
10 
Hosseinzadeh S., Verheust Y., Bonarrigo G., Van Hulle S., 2017, Closed hydroponic systems: Operational parameters, root exudates occurrence and related water treatment, Reviews in Environmental Science and Bio/Technology, Vol. 16, No. 1, pp. 59-79DOI
11 
Inderjit , Duke S. O., 2003, Ecophysiological aspects of allelopathy, Planta, Vol. 217, No. 4, pp. 529-539DOI
12 
Issa H. M., Mohammed D. H., 2025, A critical review on the journey of benzoic acid in the pharmaceutical industry from manufacturing processes through various uses to disposal: An environmental perspective, Environmental Analysis Health and Toxicology, Vol. 40, No. 1, pp. e2025007DOI
13 
Johnson G. R., Brusseau M. L., Carroll K. C., Tick G. R., Duncan C. M., 2022, Global distributions, source-type dependencies, and concentration ranges of per- and polyfluoroalkyl substances in groundwater, Science of the Total Environment, Vol. 841, pp. 156602DOI
14 
Jang Y. J., 2024, Strategy for revitalizing the smart farm industry in Korea: Focusing on policies of major countries and global best practices, Trade Focus, Vol. 2024, No. 13Google Search
15 
Kovacic P., Somanathan R., 2014, Nitroaromatic compounds: Environmental toxicity, carcinogenicity, mutagenicity, therapy and mechanism, Journal of Applied Toxicology, Vol. 34, No. 8, pp. 810-824DOI
16 
Krasner S. W., Weinberg H. S., Richardson S. D., Pastor S. J., Chinn R., Sclimenti M. J., Onstad G. D., Thruston A. D., 2006, Occurrence of a new generation of disinfection byproducts, Environmental Science & Technology, Vol. 40, No. 23, pp. 7175-7185DOI
17 
Kuzmanović M., Ginebreda A., Petrović M., Barceló D., 2015, Risk assessment based prioritization of 200 organic micropollutants in 4 Iberian rivers, Science of the Total Environment, Vol. 503–504, pp. 289-299DOI
18 
Kwon Y. K., Cho H. J., Ko S. H., 2018, Study on damage radius in case of chlorine gas and ozone gas leakage in water treatment plants, Journal of the Korean Society for Fluid Machinery, Vol. 21, No. 2, pp. 35-40DOI
19 
Lee Y., von Gunten U., 2010, Oxidative transformation of micropollutants during municipal wastewater treatment: Comparison of kinetic aspects of selective (chlorine, chlorine dioxide, ferrate VI, and ozone) and non-selective oxidants (hydroxyl radical), Water Research, Vol. 44, No. 2, pp. 555-566DOI
20 
Lee Y., Yoon J., von Gunten U., 2005, Spectrophotometric determination of ferrate (Fe(VI)) in water by ABTS, Water Research, Vol. 39, pp. 1946-1953DOI
21 
Lee Y., Zimmermann S. G., Kieu A. T., von Gunten U., 2009, Ferrate (Fe(VI)) application for municipal wastewater treatment: a novel process for simultaneous micropollutant oxidation and phosphate removal, Environmental Science & Technology, Vol. 43, No. 10, pp. 3831-3838DOI
22 
Lei X., Guan J., Fan M., Lei Y., Qiu J., Yang X., 2024, Aromatic structures govern the formation of chlorinated byproducts in dichlorine radical reactions, Environmental Science & Technology, Vol. 58, No. 7, pp. 3871-3880DOI
23 
Matilainen A., Gjessing E. T., Lahtinen T., Hed L., Bhatnagar A., Sillanpää M., 2011, An overview of the methods used in the characterization of natural organic matter (NOM) in relation to drinking water treatment, Chemosphere, Vol. 83, No. 11, pp. 1431-1442DOI
24 
McKnight D. M., Hood E., Klapper L., 2003, Trace organic moieties of dissolved organic material in natural waters, Aquatic Ecosystems, pp. 71-96DOI
25 
Park M., 2024, Smart agriculture and agricultural sector employment status and prospects, World Agriculture, Vol. E03-2024-4-2, pp. 33-48Google Search
26 
Plewa M. J., Wagner E. D., Richardson S. D., Thruston A. D., Jr, Woo Y. T., McKague A. B., 2004, Chemical and biological characterization of newly discovered iodoacid drinking water disinfection byproducts, Environmental Science & Technology, Vol. 38, No. 18, pp. 4713-4722DOI
27 
Qi X., Ding L., Jian C., Liu R., 2024, Ferrate(VI) oxidation of substituted nitrobenzene compounds: kinetics, degradation, and oxidized products, Chemical Engineering Journal, Vol. 488, pp. 150921DOI
28 
Richardson S. D., 2003, Disinfection by-products and other emerging contaminants in drinking water, Trends in Analytical Chemistry, Vol. 22, No. 10, pp. 666-684DOI
29 
Richardson S. D., Ternes T. A., 2021, Water analysis: Emerging contaminants and current issues, Analytical Chemistry, Vol. 94, No. 1, pp. 382-416DOI
30 
Richardson S. D., Ternes T. A., 2014, Water analysis: Emerging contaminants and current issues, Analytical Chemistry, Vol. 86, No. 6, pp. 2813-2848DOI
31 
Rougé V., Pressman J. G., Wahman D. G., Mitch W. A., 2022, Nitriles as main products from the oxidation of primary amines by ferrate (VI): Kinetics, mechanisms and toxicological implications for nitrogenous disinfection byproduct control, Water Research, Vol. 209, pp. 117881DOI
32 
Ryu J., Kim H., Jeong A., 2018, Water pollution management measures for new agricultural facilities, Policy Report: 2018-07, pp. 79Google Search
33 
Sharma V. K., 2011, Oxidation of inorganic contaminants by ferrates (VI, V, and IV) – kinetics and mechanisms: A review, Journal of Environmental Management, Vol. 92, No. 4, pp. 1051-1073DOI
34 
Sharma V. K., O’Connor D. B., 2008, Ferrate (VI) oxidation of endocrine disruptors and antimicrobials in water, Journal of Environmental Science and Health, Part A, Vol. 43, No. 11, pp. 1165-1171DOI
35 
Sharma V. K., Mishra S. K., Nesnas N., 2001, Dissociation constants of the monoprotic ferrate (VI) ion in NaCl media, Physical Chemistry Chemical Physics, Vol. 3, pp. 2059-2062DOI
36 
Shi W., Zhang C., Zhao H., Tang H., Liu Y., Zhang B., 2025, Low ultraviolet dose with high efficiency: Synergistic coupling of far-UVC and ferrate (VI) for ultrafast and selective degradation of micropollutants, Water Research, Vol. 282, pp. 123785DOI
37 
Shin J., Lee Y., 2016, Elimination of organic contaminants during oxidative water treatment with ferrate (VI): Reaction kinetics and transformation products, Ferrites and Ferrates: Chemistry and Applications in Sustainable Energy and Environmental Remediation, Vol. 1238, pp. 255-273DOI
38 
Shin J., Lee D., Hwang T. M., Lee Y., 2018, Oxidation kinetics of algal-derived taste and odor compounds during water treatment with ferrate(VI), Chemical Engineering Journal, Vol. 334, pp. 1065-1073DOI
39 
Song M., McKenna E., Ferrer I., Thurman E. M., Taylor-Edmonds L., Hofmann R., Ishida K., Roback S., Plumlee M., Hanigan D., 2023, Comparison of oxidants used in advanced oxidation for potable reuse: Non-target analysis and bioassays, ACS ES&T Water, Vol. 3, No. 3, pp. 690-700DOI
40 
Sun S., Liu Y., Ma J., Pang S., Huang Z., Gu J., Gao Y., Xue M., Yuan Y., Jiang J., 2018, Transformation of substituted anilines by ferrate(VI): Kinetics, pathways, and effect of dissolved organic matter, Chemical Engineering Journal, Vol. 332, pp. 245-252DOI
41 
Tekle-Röttering A., von Sonntag C., Reisz E., vom Eyser C., Lutze H. V., Türk J., Naumov S., Schmidt W., Schmidt T. C., 2016, Ozonation of anilines: Kinetics, stoichiometry, product identification and elucidation of pathways, Water Research, Vol. 98, pp. 147-159DOI
42 
Tiwari J., Tarale P., Sivanesan S., Bafana A., 2019, Environmental persistence, hazard, and mitigation challenges of nitroaromatic compounds, Environmental Science and Pollution Research, Vol. 26, No. 28, pp. 28650-28667DOI
43 
Van Antwerpen P., Dubois J., Gelbcke M., Neve J., 2004, The reactions of oxicam and sulfoanilide non steroidal anti-inflammatory drugs with hypochlorous acid: Determination of the rate constants with an assay based on the competition with para-aminobenzoic acid chlorination and identification of some oxidation products, Free Radical Research, Vol. 38, No. 3, pp. 251-258DOI
44 
Villanueva C. M., Cordier S., Font-Ribera L., Salas L. A., Levallois P., 2015, Overview of disinfection by-products and associated health effects, Current Environmental Health Reports, Vol. 2, No. 1, pp. 107-115DOI
45 
Wang C., Zhu Y., Andrews S. A., Hofmann R., 2022, Effect of UV/chlorine oxidation on disinfection byproduct formation from diverse model compounds, ACS ES&T Water, Vol. 2, No. 4, pp. 625-634DOI
46 
Wang D., Yu Y., He J., Ma J., Zhang J., Strathmann T. J., 2024, Comprehending the practical implementation of permanganate and ferrate for water remediation in complex water matrices, Journal of Hazardous Materials, Vol. 462, pp. 132659DOI
47 
Weston L. A., Duke S. O., 2003, Weed and crop allelopathy, Critical Reviews in Plant Sciences, Vol. 22, No. 3–4, pp. 367-389DOI
48 
Xue J., Zhao Y., Li Z., 2021, Per- and polyfluoroalkyl substances in water and wastewater: A critical review of their global occurrence and distribution, Science of the Total Environment, Vol. 809, pp. 151003DOI
49 
Xue Y., Sun W., Shao P., Yuan Y., Cui F., Shi W., 2023, Degradation of contaminants of PPCPs by photocatalysis for water purification: kinetics, mechanisms, and cytotoxicity analysis, Chemical Engineering Journal, Vol. 454, pp. 140505DOI
50 
Yang X., Rosario-Ortiz F. L., Lei Y., Pan Y., Lei X., Westerhoff P., 2022, Multiple roles of dissolved organic matter in advanced oxidation processes, Environmental Science & Technology, Vol. 56, No. 16, pp. 11111-11131DOI
51 
Yoon Y., Cho M., 2024, Understanding atrazine elimination via treatment of the enzyme-based Fenton reaction: Kinetics, mechanism, reaction pathway, and metabolites toxicity, Chemosphere, Vol. 349, pp. 140982DOI
52 
Zeng R. S., Mallik A. U., Luo S. M., 2008, Allelopathy in sustainable agriculture and forestry, Allelopathy in Sustainable Agriculture and Forestry, Springer Series in AllelopathyGoogle Search
53 
Zhang H., Zheng L., Li Z., Pi K., Deng Y., 2020, One-step ferrate(VI) treatment as a core process for alternative drinking water treatment, Chemosphere, Vol. 242, pp. 125134DOI
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