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Bibliometric analysis of disinfection by-product research trends in Türkiye

Year 2023, Volume: 6 Issue: 3, 173 - 182, 30.09.2023
https://doi.org/10.35208/ert.1271094

Abstract

The goal of this study is to reveal the time dynamics of studies systematically and comprehensively on drinking water treatment and disinfection, as well as the situation in the literature, by using the bibliometric analysis method to examine scientific publications in the field of "Disinfection By-Products" between 2001 and 2022. The data gathered from the investigated articles is shown using the visual mapping approach. In this regard, the research provides for an evaluation of the disinfection by-products literature. The study's database contained 115 scientific papers retrieved from Web of Science. Istanbul Technical University is the most productive university with 23 published articles on Disinfection By-products, followed by Suleyman Demirel University with 18 published articles. Trihalomethanes, haloacetic acids are the most studied types of carbonaceous disinfection by-products in published articles, and N-nitrosodimethylamine is one of the most widely published nitrogenous disinfection by-products. The precursors of disinfection by-products or the removal of disinfection by-products are the two main focuses of the purpose of all studies. Coagulation, advanced oxidation processes and membrane processes constitute the methods used in the control of disinfection by-products. Brominated, and nitrogenous DBPs have attracted much attention due to their high toxicity. Future studies on disinfection by-products should focus on water quality standards, precursor controls, toxicity, and health effects. The necessity of bibliometric analysis of disinfection by-products is a necessity to fill the existing knowledge gaps in global and regional studies.

References

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  • A. Latifoglu, “Formation of trihalomethanes by the disinfection of drinking water,” Indoor and Built Environment, Vol. 12(6), pp. 413–417, 2003. [CrossRef]
  • M. Kitis, “Disinfection of wastewater with peracetic acid: a review,” Environment International, Vol. 30(1), pp. 47–55, 2004. [CrossRef]
  • B. Tokmak, G. Capar, F. B. Dilek, and U. Yetis, “Trihalomethanes and associated potential cancer risks in the water supply in Ankara, Turkey,” Environmental Research, Vol. 96(3), pp. 345–352, 2004. [CrossRef]
  • V. Uyak, I. Toroz, and S. Meric, “Monitoring and modeling of trihalomethanes (THMs) for a water treatment plant in Istanbul,” Desalination, Vol. 176(1–3), pp. 91–101, 2005. [CrossRef]
  • V. Uyak, S. Senay, T. Topal, N. Karapinar, K. Ozdemir, S. Ozaydin, and E. Avsar, “Spatial and seasonal variations of disinfection byproducts (DBPs) in drinking water distribution systems of Istanbul city, Turkey,” Environmental Forensics, Vol. 15(2), pp. 190–205, 2014. [CrossRef]
  • E. Avsar, I. Toroz, A. Hanedar, and M. Yilmaz, “Chemical characterization of natural organic matter and determination of disinfection by-product formation potentials in surface waters of Istanbul (Omerli and Buyukcekmece Water Dam), Turkey,” Fresenius Environmental Bulletin, Vol. 23(2A), pp. 494–501, 2014. [CrossRef]
  • P. Kavcar, M. Odabasi, M. Kitis, S. C. Inal Fikret, and Sofuoglu, “Occurrence, oral exposure and risk assessment of volatile organic compounds in drinking water for Izmir,” Water Research, Vol. 40(17), pp. 3219–3230, 2006. [CrossRef]
  • N. Ates, S. S. Kaplan, E. Sahinkaya, F. B. Dilek, M. Kitis, and U. Yetis, “Occurrence of disinfection by-products in low DOC surface waters in Turkey,” Journal of Hazardous Materials, Vol. 142(1–2), pp. 526–534, 2007. [CrossRef]
  • M. Bekbolet, C. S. Uyguner, H. Selcuk, L. Rizzo, A. D. Nikolaou, S. Meric, and V. Belgiorno, “Application of oxidative removal of NOM to drinking water and formation of disinfection by-products,” Desalination, Vol. 176(1–3), pp. 155–166, 2005. [CrossRef]
  • C. S. Uyguner, S. A. Suphandag, A. Kerc, and M. Bekbolet, “Evaluation of adsorption and coagulation characteristics of humic acids preceded by alternative advanced oxidation techniques,” Desalination, Vol. 210(1–3), pp. 183–193, 2007. [CrossRef]
  • M. Kitis, S. S. Kaplan, E. Karakaya, N. O. Yigit, and G. Civelekoglu, “Adsorption of natural organic matter from waters by iron coated pumice,” Chemosphere, Vol. 66(1), pp. 130–138, 2007. [CrossRef]
  • V. Uyak, S. Yavuz, I. Toroz, S. Ozaydin, and E. A. Genceli, “Disinfection by-products precursors removal by enhanced coagulation and PAC adsorption,” Desalination, Vol. 216(1–3), pp. 334–344, 2007. [CrossRef]
  • N. Ates, U. Yetis, and M. Kitis, “Effects of bromide ion and natural organic matter fractions on the formation and speciation of chlorination by-products,” Journal of Environmental Engineering, Vol. 133(10), pp. 947–954, 2007. [CrossRef]
  • V. Uyak, “Multi-pathway risk assessment of trihalomethanes exposure in Istanbul drinking water supplies,” Environment International, Vol. 32(1), pp. 12–21, 2006. [CrossRef]
  • V. Uyak, and I. Toroz, “Modeling the formation of chlorination by-products during enhanced coagulation,” Environmental Monitoring and Assessment, Vol. 121(1–3), pp. 503–517, 2006. [CrossRef]
  • V. Uyak, K. Ozdemir, and I. Toroz, “Multiple linear regression modeling of disinfection by-products formation in Istanbul drinking water reservoirs,” Science of The Total Environment, Vol. 378(3), pp. 269–280, 2007. [CrossRef]
  • E. Avsar, I. Toroz, and A. Hanedar, “Physical characterisation of natural organic matter and determination of disinfection by-product formation potentials in Istanbul surface waters,” Fresenius Environmental Bulletin, Vol. 24(9), pp. 2763–2770, 2015. [CrossRef]
  • V. Uyak, and I. Toroz, “Investigation of bromide ion effects on disinfection by-products formation and speciation in an Istanbul water supply,” Journal of Hazardous Materials, Vol. 149(2), pp. 445–451, 2007. [CrossRef]
  • G. Civelekoglu, N. O. Yigit, E. Diamadopoulos, and M. Kitis, “Prediction of bromate formation using multi-linear regression and artificial neural networks,” Ozone-Science & Engineering, Vol. 29(5), pp. 353–362, 2007. [CrossRef]
  • H. Selcuk, L. Rizzo, A. N. Nikolaou, S. Meric, V. Belgiorno, and M. Bekbolet, “DBPs formation and toxicity monitoring in different origin water treated by ozone and alum/PAC coagulation,” Desalination, Vol. 210(1–3), pp. 31–43, 2007. [CrossRef]
  • D. Baytak, A. Sofuoglu, F. Inal, and S. C. Sofuoglu, “Seasonal variation in drinking water concentrations of disinfection by-products in Izmir and associated human health risks,” Science of The Total Environment, Vol. 407(1), pp. 286–296, 2008. [CrossRef]
  • A. Teksoy, U. Alkan, and H. S. Baskaya, “Influence of the treatment process combinations on the formation of THM species in water,” Separation and Purification Technology, Vol. 61(3), pp. 447–454, 2008. [CrossRef]
  • M. Kitis, N. O. Yigita, B. I. Harmana, H. Muhammetoglu, A. Muhammetoglu, I. E. Karadirek, I. Demirel, T. Ozdenc, and I. Palancic, “Occurrence of trihalomethanes in chlorinated groundwaters with very low natural organic matter and bromide concentrations,” Environmental Forensics, Vol. 11(3), pp. 264–274, 2010. [CrossRef]
  • G. Kara, S. Tongur, and M. E. Aydin, “Factors Influencing Formation of Disinfection By-Products in Six Drinking Water Reservoirs (Konya, Turkey),” Fresenius Environmental Bulletin, Vol. 20(7A), pp. 1821–1826, 2011.
  • S. Kucukcongar, M. F. Sevimli, and E. Yel, “DBP formation and speciation in a central Anatolian dam water depending on pH, TOC level, fraction and chlorine dose,” Global Nest Journal, Vol. 15(4), pp. 447–456, 2013. [CrossRef]
  • M. U. Akcay, Z. Y. Avdan, and H. Inan, “Effect of biofiltration process on the control of THMs and HAAs in drinking water,” Desalination Water Treat, Vol. 57(6), pp. 2546–2554, 2016. [CrossRef]
  • A. Alver, M. Karaarslan, and A. Kilic, “The catalytic activity of the iron-coated pumice particles used as heterogeneous catalysts in the oxidation of natural organic matter by H2O2,” Environmental Technology, Vol. 37(16), pp. 2040–2047, 2016. [CrossRef]
  • K. Ozdemir, “Experimental investigation of trihalomethanes removal in chlorinated drinking water sources with carbon nanomaterials,” Fresenius Environmental Bulletin, Vol. 25(12A), pp. 6202–6214, 2016. [CrossRef]
  • T. Uysal, S. Yilmaz, M. Turkoglu, and M. Sadikoglu, “Investigation of some disinfection chemicals and water quality parameters in swimming pools in the city center and districts of Çanakkale, Turkey,” Environmental Monitoring and Assessment, Vol. 189(7), Article 338, 2017. [CrossRef]
  • E. Avsar, D. D. Avsar, and S. Hayta, “Evaluation of disinfection by-product (DBP) formation and fingerprint in a swimming pool in Bitlis/Turkey: a case study,” Environmental Forensics, Vol. 21(3–4), pp. 375–385, 2020. [CrossRef]
  • Z. Yigit Avdan, S. Goncu, and E. T. Mizik, “Evaluation of Trihalomethane Formation Risk Analysis in Swimming Pools in Eskisehir, Turkey,” Environmental Forensics, 2022. [Epub ahead of print] doi: 10.1080/15275922.2022.2047829. [CrossRef]
  • E. Pehlivanoglu-Mantas, and D. L. Sedlak, “Measurement of dissolved organic nitrogen forms in wastewater effluents: Concentrations, size distribution and NDMA formation potential,” Water Research, Vol. 42(14), pp. 3890–3898, 2008. [CrossRef]
  • E. Aydin, F. B. Yaman, E. A. Genceli, E. Topuz, E. Erdim, M. Gurel, … El. Pehlivanoglu-Mantas, “Occurrence of THM and NDMA precursors in a watershed: Effect of seasons and anthropogenic pollution,” Journal of Hazardous Materials, Vol. 221, pp. 86–91, 2012. [CrossRef]
  • J. Shan, J. Hu, S. S. Kaplan-Bekaroglu, H. Song, and T. Karanfil, “The effects of pH, bromide and nitrite on halonitromethane and trihalomethane formation from amino acids and amino sugars,” Chemosphere, Vol. 86(4), pp. 323–328, 2012. [CrossRef]
  • X. Gan, T. Karanfil, S. S. K. Bekaroglu, and J. Shan, “The control of N-DBP and C-DBP precursors with MIEX (R),” Water Research, Vol. 47(3), pp. 1344–1352. [CrossRef]
  • E. Topuz, E. Aydin, and E. Pehlivanoglu-Mantas, “A practical LC-MS/MS method for the detection of ndma at nanogram per liter concentrations in multiple water matrices,” Water, Air, & Soil Pollution, Vol. 223(9), pp. 5793–5802, 2012. [CrossRef]
  • M. Selbes, D. Kim, N. Ates, and T. Karanfil, “The roles of tertiary amine structure, background organic matter and chloramine species on NDMA formation,” Water Research, Vol. 47(2), pp. 945–953, 2013. [CrossRef]
  • N. H. Orak, T. Ozsenturk, E. Topuz, E. Aydin, M. Gurel, and E. A. Genceli, and E. Pehlivanoglu-Mantas, “Effect of disinfection processes and anthropogenic pollutants on comparative formation of trihalomethanes and N-nitrosodimethylamine,” International Journal of Environmental Science and Technology, Vol. 16(8), pp. 4083–4090, 2019. [CrossRef]
  • H. Uzun, D. Kim, and T. Karanfil, “Removal of wastewater and polymer derived N-nitrosodimethylamine precursors with integrated use of chlorine and chlorine dioxide,” Chemosphere, Vol. 216, pp. 224–233, 2019. [CrossRef]
  • H. Majidzadeh, H. Uzun, H. Chen, S. Bao, M. T.-K. Tsui, T. Karanfil, and A. T. Chow, “Hurricane resulted in releasing more nitrogenous than carbonaceous disinfection byproduct precursors in coastal watersheds,” Science of The Total Environment, Vol. 705, Article 135785, 2020. [CrossRef]
  • C. Ozgur, and S. S. Kaplane-Bekaroglu, “Carbonaceous disinfection by-products in low SUVA waters: Occurrence, formation potntial, and health risk assessment,” Applied Ecology and Environmental Research, Vol. 20(5), pp. 38333851, 2022. [CrossRef]
  • M. Duque-Acevedo, L. J. Belmonte-Ureña, F. J. Cortés-García, and F. Camacho-Ferre, “Agricultural waste: Review of the evolution, approaches and perspectives on alternative uses,” Global Ecology and Conservation, Vol. 22, Article e00902, 2020. [CrossRef]
  • G. Goel, C. Hélix-Nielsen, H. M. Upadhyaya, and S. Goel, “A bibliometric study on biomimetic and bioinspired membranes for water filtration,” npj Clean Water, Vol. 4(1), Article 41, 2021. [CrossRef]
  • V. Uyak, I. Koyuncu, I. Oktem, and I. Cakmakci Mehmet and Toroz, “Removal of trihalomethanes from drinking water by nanofiltration membranes,” Journal of Hazardous Materials, Vol. 152(2), pp. 789–794, 2008. [CrossRef]
  • N. Ates, L. Yilmaz, M. Kitis, and U. Yetis, “Removal of disinfection by-product precursors by UF and NF membranes in low-SUVA waters,” Journal of Membrane Science, Vol. 328(1–2), pp. 104–112, 2009. [CrossRef]
  • B. I. Harman, H. Koseoglu, N. O. Yigit, E. Sayilgan, M. Beyhan, and M. Kitis, “The removal of disinfection by-product precursors from water with ceramic membranes,” Water Science and Technology, Vol. 62(3), pp. 547–555, 2010. [CrossRef]
  • S. W. Krasner, A. Jia, C.-F. T. Lee, R. Shirkhani, J. M. Allen, S. D. Richardson, and M. J. Plewa, “Relationships between regulated DBPs and emerging DBPs of health concern in U.S. drinking water,” Journal of Environmental Sciences, Vol. 117, pp. 161–172, 2022. [CrossRef]
  • E. Demir, B. Kaya, A. Creus, and R. Marcos, “Genotoxic evaluation of the disinfection by-products mucochloric and mucobromic acids in drosophila melanogaster,” Fresenius Environmental Bulletin, Vol. 21(12A), pp. 3864–3868, 2012.
  • M. Genisoglu, C. Ergi-Kaytmaz, and S. C. Sofuoglu, “Multi-route - Multi-pathway exposure to trihalomethanes and associated cumulative health risks with response and dose addition,” Journal of Environmental Management, Vol. 233, pp. 823–831. [CrossRef]
  • B. C. Vizioli, L. W. Hantao, and C. C. Montagner, “Disinfection byproducts in emerging countries,” in Emerging Freshwater Pollutants, pp. 241–266, 2022. [CrossRef]
  • A. Kanan, M. Soyluoglu, and T. Karanfil, “Removal of the precursors of regulated DBPs and TOX from surface waters and wastewater effluents using mixed anion exchange resins,” Chemosphere, Vol. 263, Article 128094, 2021. [CrossRef]
  • F. B. Yaman, M. Cakmakci, E. Yuksel, I. Ozen, and E. Gengec, “Removal of micropollutants from Sakarya River water by ozone and membrane processes,” Environmental Monitoring and Assessment, Vol. 189(9), Article 438, 2017. [CrossRef]
  • K.-P. Tsai, H. Uzun, H. Chen, K. Tanju, and 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, Vol. 158, pp. 227–236, 2019. [CrossRef]
  • K. Ozdemir, and O. Gungor, “Development of statistical models for trihalomethane (THM) removal in drinking water sources using carbon nanotubes (CNTs),” Water SA, Vol. 44(4), pp. 680–690, 2018. [CrossRef]
Year 2023, Volume: 6 Issue: 3, 173 - 182, 30.09.2023
https://doi.org/10.35208/ert.1271094

Abstract

References

  • M. J. Kirisits, V. L. Snoeyink, H. Inan, J. C. Chee-Sanford, L. Raskin, and J. C. Brown, “Water quality factors affecting bromate reduction in biologically active carbon filters,” Water Research, Vol. 35(4), pp. 891–900, 2001. [CrossRef]
  • A. Latifoglu, “Formation of trihalomethanes by the disinfection of drinking water,” Indoor and Built Environment, Vol. 12(6), pp. 413–417, 2003. [CrossRef]
  • M. Kitis, “Disinfection of wastewater with peracetic acid: a review,” Environment International, Vol. 30(1), pp. 47–55, 2004. [CrossRef]
  • B. Tokmak, G. Capar, F. B. Dilek, and U. Yetis, “Trihalomethanes and associated potential cancer risks in the water supply in Ankara, Turkey,” Environmental Research, Vol. 96(3), pp. 345–352, 2004. [CrossRef]
  • V. Uyak, I. Toroz, and S. Meric, “Monitoring and modeling of trihalomethanes (THMs) for a water treatment plant in Istanbul,” Desalination, Vol. 176(1–3), pp. 91–101, 2005. [CrossRef]
  • V. Uyak, S. Senay, T. Topal, N. Karapinar, K. Ozdemir, S. Ozaydin, and E. Avsar, “Spatial and seasonal variations of disinfection byproducts (DBPs) in drinking water distribution systems of Istanbul city, Turkey,” Environmental Forensics, Vol. 15(2), pp. 190–205, 2014. [CrossRef]
  • E. Avsar, I. Toroz, A. Hanedar, and M. Yilmaz, “Chemical characterization of natural organic matter and determination of disinfection by-product formation potentials in surface waters of Istanbul (Omerli and Buyukcekmece Water Dam), Turkey,” Fresenius Environmental Bulletin, Vol. 23(2A), pp. 494–501, 2014. [CrossRef]
  • P. Kavcar, M. Odabasi, M. Kitis, S. C. Inal Fikret, and Sofuoglu, “Occurrence, oral exposure and risk assessment of volatile organic compounds in drinking water for Izmir,” Water Research, Vol. 40(17), pp. 3219–3230, 2006. [CrossRef]
  • N. Ates, S. S. Kaplan, E. Sahinkaya, F. B. Dilek, M. Kitis, and U. Yetis, “Occurrence of disinfection by-products in low DOC surface waters in Turkey,” Journal of Hazardous Materials, Vol. 142(1–2), pp. 526–534, 2007. [CrossRef]
  • M. Bekbolet, C. S. Uyguner, H. Selcuk, L. Rizzo, A. D. Nikolaou, S. Meric, and V. Belgiorno, “Application of oxidative removal of NOM to drinking water and formation of disinfection by-products,” Desalination, Vol. 176(1–3), pp. 155–166, 2005. [CrossRef]
  • C. S. Uyguner, S. A. Suphandag, A. Kerc, and M. Bekbolet, “Evaluation of adsorption and coagulation characteristics of humic acids preceded by alternative advanced oxidation techniques,” Desalination, Vol. 210(1–3), pp. 183–193, 2007. [CrossRef]
  • M. Kitis, S. S. Kaplan, E. Karakaya, N. O. Yigit, and G. Civelekoglu, “Adsorption of natural organic matter from waters by iron coated pumice,” Chemosphere, Vol. 66(1), pp. 130–138, 2007. [CrossRef]
  • V. Uyak, S. Yavuz, I. Toroz, S. Ozaydin, and E. A. Genceli, “Disinfection by-products precursors removal by enhanced coagulation and PAC adsorption,” Desalination, Vol. 216(1–3), pp. 334–344, 2007. [CrossRef]
  • N. Ates, U. Yetis, and M. Kitis, “Effects of bromide ion and natural organic matter fractions on the formation and speciation of chlorination by-products,” Journal of Environmental Engineering, Vol. 133(10), pp. 947–954, 2007. [CrossRef]
  • V. Uyak, “Multi-pathway risk assessment of trihalomethanes exposure in Istanbul drinking water supplies,” Environment International, Vol. 32(1), pp. 12–21, 2006. [CrossRef]
  • V. Uyak, and I. Toroz, “Modeling the formation of chlorination by-products during enhanced coagulation,” Environmental Monitoring and Assessment, Vol. 121(1–3), pp. 503–517, 2006. [CrossRef]
  • V. Uyak, K. Ozdemir, and I. Toroz, “Multiple linear regression modeling of disinfection by-products formation in Istanbul drinking water reservoirs,” Science of The Total Environment, Vol. 378(3), pp. 269–280, 2007. [CrossRef]
  • E. Avsar, I. Toroz, and A. Hanedar, “Physical characterisation of natural organic matter and determination of disinfection by-product formation potentials in Istanbul surface waters,” Fresenius Environmental Bulletin, Vol. 24(9), pp. 2763–2770, 2015. [CrossRef]
  • V. Uyak, and I. Toroz, “Investigation of bromide ion effects on disinfection by-products formation and speciation in an Istanbul water supply,” Journal of Hazardous Materials, Vol. 149(2), pp. 445–451, 2007. [CrossRef]
  • G. Civelekoglu, N. O. Yigit, E. Diamadopoulos, and M. Kitis, “Prediction of bromate formation using multi-linear regression and artificial neural networks,” Ozone-Science & Engineering, Vol. 29(5), pp. 353–362, 2007. [CrossRef]
  • H. Selcuk, L. Rizzo, A. N. Nikolaou, S. Meric, V. Belgiorno, and M. Bekbolet, “DBPs formation and toxicity monitoring in different origin water treated by ozone and alum/PAC coagulation,” Desalination, Vol. 210(1–3), pp. 31–43, 2007. [CrossRef]
  • D. Baytak, A. Sofuoglu, F. Inal, and S. C. Sofuoglu, “Seasonal variation in drinking water concentrations of disinfection by-products in Izmir and associated human health risks,” Science of The Total Environment, Vol. 407(1), pp. 286–296, 2008. [CrossRef]
  • A. Teksoy, U. Alkan, and H. S. Baskaya, “Influence of the treatment process combinations on the formation of THM species in water,” Separation and Purification Technology, Vol. 61(3), pp. 447–454, 2008. [CrossRef]
  • M. Kitis, N. O. Yigita, B. I. Harmana, H. Muhammetoglu, A. Muhammetoglu, I. E. Karadirek, I. Demirel, T. Ozdenc, and I. Palancic, “Occurrence of trihalomethanes in chlorinated groundwaters with very low natural organic matter and bromide concentrations,” Environmental Forensics, Vol. 11(3), pp. 264–274, 2010. [CrossRef]
  • G. Kara, S. Tongur, and M. E. Aydin, “Factors Influencing Formation of Disinfection By-Products in Six Drinking Water Reservoirs (Konya, Turkey),” Fresenius Environmental Bulletin, Vol. 20(7A), pp. 1821–1826, 2011.
  • S. Kucukcongar, M. F. Sevimli, and E. Yel, “DBP formation and speciation in a central Anatolian dam water depending on pH, TOC level, fraction and chlorine dose,” Global Nest Journal, Vol. 15(4), pp. 447–456, 2013. [CrossRef]
  • M. U. Akcay, Z. Y. Avdan, and H. Inan, “Effect of biofiltration process on the control of THMs and HAAs in drinking water,” Desalination Water Treat, Vol. 57(6), pp. 2546–2554, 2016. [CrossRef]
  • A. Alver, M. Karaarslan, and A. Kilic, “The catalytic activity of the iron-coated pumice particles used as heterogeneous catalysts in the oxidation of natural organic matter by H2O2,” Environmental Technology, Vol. 37(16), pp. 2040–2047, 2016. [CrossRef]
  • K. Ozdemir, “Experimental investigation of trihalomethanes removal in chlorinated drinking water sources with carbon nanomaterials,” Fresenius Environmental Bulletin, Vol. 25(12A), pp. 6202–6214, 2016. [CrossRef]
  • T. Uysal, S. Yilmaz, M. Turkoglu, and M. Sadikoglu, “Investigation of some disinfection chemicals and water quality parameters in swimming pools in the city center and districts of Çanakkale, Turkey,” Environmental Monitoring and Assessment, Vol. 189(7), Article 338, 2017. [CrossRef]
  • E. Avsar, D. D. Avsar, and S. Hayta, “Evaluation of disinfection by-product (DBP) formation and fingerprint in a swimming pool in Bitlis/Turkey: a case study,” Environmental Forensics, Vol. 21(3–4), pp. 375–385, 2020. [CrossRef]
  • Z. Yigit Avdan, S. Goncu, and E. T. Mizik, “Evaluation of Trihalomethane Formation Risk Analysis in Swimming Pools in Eskisehir, Turkey,” Environmental Forensics, 2022. [Epub ahead of print] doi: 10.1080/15275922.2022.2047829. [CrossRef]
  • E. Pehlivanoglu-Mantas, and D. L. Sedlak, “Measurement of dissolved organic nitrogen forms in wastewater effluents: Concentrations, size distribution and NDMA formation potential,” Water Research, Vol. 42(14), pp. 3890–3898, 2008. [CrossRef]
  • E. Aydin, F. B. Yaman, E. A. Genceli, E. Topuz, E. Erdim, M. Gurel, … El. Pehlivanoglu-Mantas, “Occurrence of THM and NDMA precursors in a watershed: Effect of seasons and anthropogenic pollution,” Journal of Hazardous Materials, Vol. 221, pp. 86–91, 2012. [CrossRef]
  • J. Shan, J. Hu, S. S. Kaplan-Bekaroglu, H. Song, and T. Karanfil, “The effects of pH, bromide and nitrite on halonitromethane and trihalomethane formation from amino acids and amino sugars,” Chemosphere, Vol. 86(4), pp. 323–328, 2012. [CrossRef]
  • X. Gan, T. Karanfil, S. S. K. Bekaroglu, and J. Shan, “The control of N-DBP and C-DBP precursors with MIEX (R),” Water Research, Vol. 47(3), pp. 1344–1352. [CrossRef]
  • E. Topuz, E. Aydin, and E. Pehlivanoglu-Mantas, “A practical LC-MS/MS method for the detection of ndma at nanogram per liter concentrations in multiple water matrices,” Water, Air, & Soil Pollution, Vol. 223(9), pp. 5793–5802, 2012. [CrossRef]
  • M. Selbes, D. Kim, N. Ates, and T. Karanfil, “The roles of tertiary amine structure, background organic matter and chloramine species on NDMA formation,” Water Research, Vol. 47(2), pp. 945–953, 2013. [CrossRef]
  • N. H. Orak, T. Ozsenturk, E. Topuz, E. Aydin, M. Gurel, and E. A. Genceli, and E. Pehlivanoglu-Mantas, “Effect of disinfection processes and anthropogenic pollutants on comparative formation of trihalomethanes and N-nitrosodimethylamine,” International Journal of Environmental Science and Technology, Vol. 16(8), pp. 4083–4090, 2019. [CrossRef]
  • H. Uzun, D. Kim, and T. Karanfil, “Removal of wastewater and polymer derived N-nitrosodimethylamine precursors with integrated use of chlorine and chlorine dioxide,” Chemosphere, Vol. 216, pp. 224–233, 2019. [CrossRef]
  • H. Majidzadeh, H. Uzun, H. Chen, S. Bao, M. T.-K. Tsui, T. Karanfil, and A. T. Chow, “Hurricane resulted in releasing more nitrogenous than carbonaceous disinfection byproduct precursors in coastal watersheds,” Science of The Total Environment, Vol. 705, Article 135785, 2020. [CrossRef]
  • C. Ozgur, and S. S. Kaplane-Bekaroglu, “Carbonaceous disinfection by-products in low SUVA waters: Occurrence, formation potntial, and health risk assessment,” Applied Ecology and Environmental Research, Vol. 20(5), pp. 38333851, 2022. [CrossRef]
  • M. Duque-Acevedo, L. J. Belmonte-Ureña, F. J. Cortés-García, and F. Camacho-Ferre, “Agricultural waste: Review of the evolution, approaches and perspectives on alternative uses,” Global Ecology and Conservation, Vol. 22, Article e00902, 2020. [CrossRef]
  • G. Goel, C. Hélix-Nielsen, H. M. Upadhyaya, and S. Goel, “A bibliometric study on biomimetic and bioinspired membranes for water filtration,” npj Clean Water, Vol. 4(1), Article 41, 2021. [CrossRef]
  • V. Uyak, I. Koyuncu, I. Oktem, and I. Cakmakci Mehmet and Toroz, “Removal of trihalomethanes from drinking water by nanofiltration membranes,” Journal of Hazardous Materials, Vol. 152(2), pp. 789–794, 2008. [CrossRef]
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There are 55 citations in total.

Details

Primary Language English
Subjects Environmental Engineering
Journal Section Research Articles
Authors

Cihan Özgür 0000-0001-6085-1585

Publication Date September 30, 2023
Submission Date March 26, 2023
Acceptance Date July 4, 2023
Published in Issue Year 2023 Volume: 6 Issue: 3

Cite

APA Özgür, C. (2023). Bibliometric analysis of disinfection by-product research trends in Türkiye. Environmental Research and Technology, 6(3), 173-182. https://doi.org/10.35208/ert.1271094
AMA Özgür C. Bibliometric analysis of disinfection by-product research trends in Türkiye. ERT. September 2023;6(3):173-182. doi:10.35208/ert.1271094
Chicago Özgür, Cihan. “Bibliometric Analysis of Disinfection by-Product Research Trends in Türkiye”. Environmental Research and Technology 6, no. 3 (September 2023): 173-82. https://doi.org/10.35208/ert.1271094.
EndNote Özgür C (September 1, 2023) Bibliometric analysis of disinfection by-product research trends in Türkiye. Environmental Research and Technology 6 3 173–182.
IEEE C. Özgür, “Bibliometric analysis of disinfection by-product research trends in Türkiye”, ERT, vol. 6, no. 3, pp. 173–182, 2023, doi: 10.35208/ert.1271094.
ISNAD Özgür, Cihan. “Bibliometric Analysis of Disinfection by-Product Research Trends in Türkiye”. Environmental Research and Technology 6/3 (September 2023), 173-182. https://doi.org/10.35208/ert.1271094.
JAMA Özgür C. Bibliometric analysis of disinfection by-product research trends in Türkiye. ERT. 2023;6:173–182.
MLA Özgür, Cihan. “Bibliometric Analysis of Disinfection by-Product Research Trends in Türkiye”. Environmental Research and Technology, vol. 6, no. 3, 2023, pp. 173-82, doi:10.35208/ert.1271094.
Vancouver Özgür C. Bibliometric analysis of disinfection by-product research trends in Türkiye. ERT. 2023;6(3):173-82.