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Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine

Yıl 2023, , 333 - 342, 31.12.2023
https://doi.org/10.24323/akademik-gida.1422793

Öz

Chlorination is one of the most important methods used in water disinfection. Chlorine reacts with natural organic substances in water and causes the formation of disinfection byproducts that might cause health problems. The predominant by-product of chlorination is trihalomethanes. Humic substances, which make up the majority of natural organic substances, are the primary precursors of trihalomethanes. In this study, the effect of different doses of chlorine on the formation of chloroform, bromodichloromethane, dibromochloromethane and bromoform in the presence of natural organic matter and bromide in drinking water was evaluated. Artificial raw water samples prepared with the addition of 2, 3 and 5 mg/L humic acid representing natural organic matter were subjected to chlorination at doses of 1, 2 and 3 mg/L and analysed on the 0th, 3rd and 7th day. The only trihalomethane formed was chloroform with a concentration of 20.52-131.13 μg/L. Increased humic acid and chlorine levels resulted in increased chloroform content. Free chlorine in the water caused chloroform formation to continue even on the 7th day. Accordingly, the amount of chloroform formed increased with the contact time. While the chlorine dose was constant, increased humic acid resulted in decreased free chlorine. To evaluate the effect of bromide on trihalomethane formation, 200 μg/L bromide was added to 2 mg/L humic acid containing water, and 1 mg/L and 2 mg/L chlorination was applied. At the end of the chlorination process in bromide-free waters, only 23.46-41.90 μg/L of chloroform was formed. In the presence of bromide, chloroform, bromodichloromethane, dibromochloromethane and bromoform were formed and the total trihalomethane level increased to 50.03-85.59 μg/L. While the ratio of brominated trihalomethane increased, the amount of chlorinated species decreased.

Kaynakça

  • [1] Çetin, B., Aloğlu, H.Ş., Uran, H., Karabulut, Ş.Y. (2016). Gıda işletmelerinde kullanılan suların gıda güvenliği yönünden incelenmesi. Akademik Gıda, 14(4), 375-381.
  • [2] Yang, X., Gan, W., Zhang, X., Huang, H., Sharma, V.K. (2015). Effect of pH on the formation of disinfection byproducts in ferrate (VI) pre-oxidation and subsequent chlorination. Separation and Purification Technology, 156, 980-986.
  • [3] Zhao, Y., Yang, H., Liu, S., Tang, S., Wang, X. (2016). Effects of metal ions on disinfection byproduct formation during chlorination of natural organic matter and surrogates. Chemosphere, 144, 1074-1082.
  • [4] Sun, X., Chen, M., Wei, D., Du, Y. (2019). Research progress of disinfection and disinfection by-products in China. Journal of Environmental Sciences, 81, 52-67.
  • [5] Pichel, N., Vivar, M., Fuentes, M. (2018). The problem of drinking water access: A review of disinfection technologies with an emphasis on solar treatment methods. Chemosphere, 218, 1014-1030.
  • [6] Chaukura, N., Marais, S.S., Moyo, W., Mbali, N., Thakalekoala, L.C., Thakalekoala, L.C., Ingwani, T., Mamba, B.B., Jarvis, P., Nkambule, T.T.I. (2020). Contemporary issues on the occurrence and removal of disinfection byproducts in drinking water - A review. Journal of Environmental Chemical Engineering, 8(2), 103659.
  • [7] Kinani, A., Kinani, S., Richard, B., Lorthioy, M., Bouchonnet, S. (2016). Formation and determination of organohalogen by-products in water–Part I. Discussing the parameters influencing the formation of organohalogen by-products and the relevance of estimating their concentration using the AOX (adsorbable organic halide) method. Trends in Analytical Chemistry, 85, 273-280.
  • [8] Sakai, H., Tokuhara, S., Murakami, M., Kosaka, K., Oguma, K., Takizawa, S. (2016). Comparison of chlorination and chloramination in carbonaceous and nitrogenous disinfection by-product formation potentials with prolonged contact time. Water Research, 88, 661-670.
  • [9] Hao, R., Zhang, Y., Du, T., Yang, L., Adeleye, A.S., Li, Y. (2017). Effect of water chemistry on disinfection by-product formation in the complex surface water system. Chemosphere, 172, 384-391.
  • [10] Ding, S., Deng, Y., Bond, T., Fang, C., Cao, Z., Chu, W. (2019). Disinfection by-product formation during drinking water treatment and distribution: A review of unintended effects of engineering agents and materials. Water Research, 160, 313-329.
  • [11] [11] Nguyen, H.V., Lee, H., Lee, S., Hur, J., Shin, H. (2021). Changes in structural characteristics of humic and fulvic acids under chlorination and their association with trihalomethanes and haloacetic acids formation. Science of the Total Environment, 790, 148142.
  • [12] [12] Cortes, C., Marcos, R. (2018). Genotoxicity of disinfection byproducts and disinfected waters: A review of recent literature. Mutation Research-Genetic Toxicology and Environmental Mutagenesis, 831, 1-12.
  • [13] Padhi, R.K., Subramanian, S., Satpathy, K.K. (2019). Formation, distribution, and speciation of DBPs (THMs, HAAs, ClO2-, and ClO3-) during treatment of different source water with chlorine and chlorine dioxide. Chemosphere, 218, 540-550.
  • [14] Zhai, H., He, X., Zhang, Y., Du, T., Adeleye, A.S., Li, Y. (2017). Disinfection byproduct formation in drinking water sources: A case study of Yuqiao reservoir. Chemosphere, 181, 224-231.
  • [15] Alexandrou, L., Meehan, B. J., Jones, O.A.H. (2018). Regulated and emerging disinfection by-products in recycled waters. Science of the Total Environment, 637-638, 1607-1616.
  • [16] Pan, Y., Li, W., An, H., Cui, H., Wang, Y. (2016). Formation and occurrence of new polar iodinated disinfection byproducts in drinking water. Chemosphere, 144, 2312-2320.
  • [17] Sinha, R., Gupta, A.K., Ghosal, P.S. (2021). A review on trihalomethanes and haloacetic acids in drinking water: Global status, health impact, insights of control and removal technologies. Journal of Environmental Chemical Engineering, 9(6), 106511.
  • [18] IARC (2022). Monographs on the identification of carcinogenic hazards to humans [online]. Website https://monographs.iarc.fr/list-of-classifications [accessed 22 03 2022].
  • [19] Moslemi, H., Davies, S.H., Masten, S.J. (2014). Hybrid ozonation–ultrafiltration: The formation of bromate in waters containing natural organic matter. Separation and Purification Technology, 125, 202-207.
  • [20] Wang,Z., An, N., Shao, Y., Gao, N., Du, E., Xu, B. (2020). Experimental and simulation investigations of UV/persulfate treatment in presence of bromide: Effects on degradation kinetics, formation of brominated disinfection byproducts and bromate. Separation and Purification Technology, 242, 116767.
  • [21] Fischbacher, A., Löppenberg, K., Sonntag, C., Schmidt, T.C. (2015). A new reaction pathway for bromite to bromate in the ozonation of bromide. Environmental Science and Technology, 49, 11714-11720.
  • [22] Legube, B., Parinet, B., Gelinet, K., Berne, F., Croue, J. (2004). Modeling of bromate formation by ozonation of surface waters in drinking water treatment. Water Research, 38, 2185-2195.
  • [23] Liu, Z., Shah, A.D., Salhi, E., Bolotin, J., von Gunten, U. (2018). Formation of brominated trihalomethanes during chlorination or ozonation of natural organic matter extracts and model compounds in saline water. Water Research, 143, 492-502.
  • [24] Zhang, Y., Zhang, N., Zhao, P., Niu, Z. (2018). Characteristics of molecular weight distribution of dissolved organic matter in bromide-containing water and disinfection by-product formation properties during treatment processes. Journal of Environmental Sciences, 65, 179-189.
  • [25] ISO 10523. Water quality (2008). - Determination of pH.
  • [26] EN 27888. Water quality (1993). Determination of electrical conductivity, 1993.
  • [27] Standard Methods for the Examination of Water & Wastewater (2005). Method # 2550, Temperature. 2/61-62. Prep. and Publ. Jointly by Am. Publ. Heath Assoc., Am. Water Works Assoc., Water. Env. Fed, 21st Edition. USA.
  • [28] Standard Methods for the Examination of Water & Wastewater (2005). Method # 2120 C, Color in water by spectrophotometry, single wavelength method 2/3-4. Prep. and Publ. Jointly by Am. Publ. Heath Assoc, Am. Water Works Assoc., Water Env. Fed, 21st Edition. USA.
  • [29] [29] EN ISO 7393-1. Water quality (2000). Determination of free chlorine and total chlorine - Part 1: Titrimetric method using N,N-diethyl-1,4-phenylenediamine.
  • [30] EN ISO 10304-1. Water quality (2009). Determination of dissolved anions by liquid chromatography of ions - Part 1: Determination of bromide, chloride, fluoride, nitrate, nitrite, phosphate and sulphate, 2009.
  • [31] EPA, Measurement of Purgeable Organic Compounds in Water by Capillary Column Gas Chromatography / Mass Spectrometry (1995). Method # 524.2. U.S. Environmental Protection Agency, Revision 4.1.
  • [32] Anonymous (2022). R development core team. R: A language and environment for statistical computing, R foundation for statistical computing, Vienna, Austria. ISBN 3-900051-07-0. https://www.R-project.org/ [accessed 22 03 2022].
  • [33] Park, K., Choi, S., Lee, S., Kweon, J. (2016). Comparison of formation of disinfection by-products by chlorination and ozonation of wastewater effluents and their toxicity to Daphnia magna. Environmental Pollution, 215, 314-321.
  • [34] Stefan, D., Erdelyi, N., Izsak, B., Zaray, G., Vargha, M. (2019). Formation of chlorination by-products in drinking water treatment plants using breakpoint chlorination. Microchemical Journal, 149, 104008.
  • [35] Akbarzadeh, S., Kaefei, R., Hashemi, S., Ramavandi, B. (2016). Data on the relationship between bromide content and the formation potential of THMs, HAAs, and HANs upon chlorination and monochloramination of Karoon River water, Iran. Data in Brief, 8, 415-419.
  • [36] Karaca, H., Velioglu, Y.S. (2009). Effects of some metals and chelating agents on patulin degradation by ozone. Ozone: Science & Engineering, 31, 224-231.
  • [37] Yu, J., Wang, Y., Wang, Q., Wang, Z., Zhang, D. et al. (2020). Implications of bromate depression from H2O2 addition during ozonation of different bromide-bearing source waters. Chemosphere, 252, 126596

Suların Klorla Dezenfeksiyonunda Trihalometan Oluşumuna Hümik Asit ve Bromürün Etkisi

Yıl 2023, , 333 - 342, 31.12.2023
https://doi.org/10.24323/akademik-gida.1422793

Öz

Suların dezenfeksiyonunda kullanılan en önemli yöntemlerden biri klorlamadır. Klor, sudaki doğal organik maddelerle reaksiyona girerek sağlık sorunlarına neden olabilecek dezenfeksiyon yan ürünlerinin oluşmasına neden olur. Klorlamanın baskın yan ürünü trihalometanlardır. Doğal organik maddelerin çoğunluğunu oluşturan hümik maddeler, trihalometanların birincil öncülleridir. Bu çalışmada farklı düzeylerde uygulanan klorun doğal organik madde ve hümik asit varlığında kloroform, bromodiklorometan, dibromoklorometan ve bromoform oluşumuna etkisi incelenmiştir. Denemede kullanılan su örnekleri, doğal organik maddeyi temsilen deiyonize suya 2, 3 ve 5 mg/L hümik asit eklenmesiyle hazırlanmış ve 1, 2 ve 3 mg/L düzeyinde klorlanarak 0., 3. ve 7. günlerde analiz edilmiştir. Oluşan tek trihalometan 20.52-131.13 μg/L düzeyindeki kloroform olmuştur. Artan hümik asit ve klor düzeyleri kloroform artışına yol açmıştır. Suda bulunan serbest formdaki klor 7. günde bile kloroform oluşturmuştur, dolayısıyla temas süresi de artışa etki etmiştir. Sabit klor dozunda artan hümik asit miktarı serbest kloru azaltmıştır. Trihalometan oluşumuna bromür iyonunun etkisini anlamak üzere 2 mg/L hümik asit içeren suya 200 μg/L bromür eklendikten sonra 1 mg/L ve 2 mg/L düzeyinde klor uygulanmıştır. Bromür içermeyen sularda klorlama işlemi sonunda sadece 23.46-41.90 μg/L düzeyinde kloroform oluşmuştur. Bromür varlığında ise kloroform, bromodiklorometan, dibromoklorometan ve bromoform oluşarak toplam trihalometan düzeyi 50.03-85.59 μg/L’ye yükselmiştir. Bromlu trihalometan oranı yükselirken klorlu türlerin miktarı azalmıştır.

Kaynakça

  • [1] Çetin, B., Aloğlu, H.Ş., Uran, H., Karabulut, Ş.Y. (2016). Gıda işletmelerinde kullanılan suların gıda güvenliği yönünden incelenmesi. Akademik Gıda, 14(4), 375-381.
  • [2] Yang, X., Gan, W., Zhang, X., Huang, H., Sharma, V.K. (2015). Effect of pH on the formation of disinfection byproducts in ferrate (VI) pre-oxidation and subsequent chlorination. Separation and Purification Technology, 156, 980-986.
  • [3] Zhao, Y., Yang, H., Liu, S., Tang, S., Wang, X. (2016). Effects of metal ions on disinfection byproduct formation during chlorination of natural organic matter and surrogates. Chemosphere, 144, 1074-1082.
  • [4] Sun, X., Chen, M., Wei, D., Du, Y. (2019). Research progress of disinfection and disinfection by-products in China. Journal of Environmental Sciences, 81, 52-67.
  • [5] Pichel, N., Vivar, M., Fuentes, M. (2018). The problem of drinking water access: A review of disinfection technologies with an emphasis on solar treatment methods. Chemosphere, 218, 1014-1030.
  • [6] Chaukura, N., Marais, S.S., Moyo, W., Mbali, N., Thakalekoala, L.C., Thakalekoala, L.C., Ingwani, T., Mamba, B.B., Jarvis, P., Nkambule, T.T.I. (2020). Contemporary issues on the occurrence and removal of disinfection byproducts in drinking water - A review. Journal of Environmental Chemical Engineering, 8(2), 103659.
  • [7] Kinani, A., Kinani, S., Richard, B., Lorthioy, M., Bouchonnet, S. (2016). Formation and determination of organohalogen by-products in water–Part I. Discussing the parameters influencing the formation of organohalogen by-products and the relevance of estimating their concentration using the AOX (adsorbable organic halide) method. Trends in Analytical Chemistry, 85, 273-280.
  • [8] Sakai, H., Tokuhara, S., Murakami, M., Kosaka, K., Oguma, K., Takizawa, S. (2016). Comparison of chlorination and chloramination in carbonaceous and nitrogenous disinfection by-product formation potentials with prolonged contact time. Water Research, 88, 661-670.
  • [9] Hao, R., Zhang, Y., Du, T., Yang, L., Adeleye, A.S., Li, Y. (2017). Effect of water chemistry on disinfection by-product formation in the complex surface water system. Chemosphere, 172, 384-391.
  • [10] Ding, S., Deng, Y., Bond, T., Fang, C., Cao, Z., Chu, W. (2019). Disinfection by-product formation during drinking water treatment and distribution: A review of unintended effects of engineering agents and materials. Water Research, 160, 313-329.
  • [11] [11] Nguyen, H.V., Lee, H., Lee, S., Hur, J., Shin, H. (2021). Changes in structural characteristics of humic and fulvic acids under chlorination and their association with trihalomethanes and haloacetic acids formation. Science of the Total Environment, 790, 148142.
  • [12] [12] Cortes, C., Marcos, R. (2018). Genotoxicity of disinfection byproducts and disinfected waters: A review of recent literature. Mutation Research-Genetic Toxicology and Environmental Mutagenesis, 831, 1-12.
  • [13] Padhi, R.K., Subramanian, S., Satpathy, K.K. (2019). Formation, distribution, and speciation of DBPs (THMs, HAAs, ClO2-, and ClO3-) during treatment of different source water with chlorine and chlorine dioxide. Chemosphere, 218, 540-550.
  • [14] Zhai, H., He, X., Zhang, Y., Du, T., Adeleye, A.S., Li, Y. (2017). Disinfection byproduct formation in drinking water sources: A case study of Yuqiao reservoir. Chemosphere, 181, 224-231.
  • [15] Alexandrou, L., Meehan, B. J., Jones, O.A.H. (2018). Regulated and emerging disinfection by-products in recycled waters. Science of the Total Environment, 637-638, 1607-1616.
  • [16] Pan, Y., Li, W., An, H., Cui, H., Wang, Y. (2016). Formation and occurrence of new polar iodinated disinfection byproducts in drinking water. Chemosphere, 144, 2312-2320.
  • [17] Sinha, R., Gupta, A.K., Ghosal, P.S. (2021). A review on trihalomethanes and haloacetic acids in drinking water: Global status, health impact, insights of control and removal technologies. Journal of Environmental Chemical Engineering, 9(6), 106511.
  • [18] IARC (2022). Monographs on the identification of carcinogenic hazards to humans [online]. Website https://monographs.iarc.fr/list-of-classifications [accessed 22 03 2022].
  • [19] Moslemi, H., Davies, S.H., Masten, S.J. (2014). Hybrid ozonation–ultrafiltration: The formation of bromate in waters containing natural organic matter. Separation and Purification Technology, 125, 202-207.
  • [20] Wang,Z., An, N., Shao, Y., Gao, N., Du, E., Xu, B. (2020). Experimental and simulation investigations of UV/persulfate treatment in presence of bromide: Effects on degradation kinetics, formation of brominated disinfection byproducts and bromate. Separation and Purification Technology, 242, 116767.
  • [21] Fischbacher, A., Löppenberg, K., Sonntag, C., Schmidt, T.C. (2015). A new reaction pathway for bromite to bromate in the ozonation of bromide. Environmental Science and Technology, 49, 11714-11720.
  • [22] Legube, B., Parinet, B., Gelinet, K., Berne, F., Croue, J. (2004). Modeling of bromate formation by ozonation of surface waters in drinking water treatment. Water Research, 38, 2185-2195.
  • [23] Liu, Z., Shah, A.D., Salhi, E., Bolotin, J., von Gunten, U. (2018). Formation of brominated trihalomethanes during chlorination or ozonation of natural organic matter extracts and model compounds in saline water. Water Research, 143, 492-502.
  • [24] Zhang, Y., Zhang, N., Zhao, P., Niu, Z. (2018). Characteristics of molecular weight distribution of dissolved organic matter in bromide-containing water and disinfection by-product formation properties during treatment processes. Journal of Environmental Sciences, 65, 179-189.
  • [25] ISO 10523. Water quality (2008). - Determination of pH.
  • [26] EN 27888. Water quality (1993). Determination of electrical conductivity, 1993.
  • [27] Standard Methods for the Examination of Water & Wastewater (2005). Method # 2550, Temperature. 2/61-62. Prep. and Publ. Jointly by Am. Publ. Heath Assoc., Am. Water Works Assoc., Water. Env. Fed, 21st Edition. USA.
  • [28] Standard Methods for the Examination of Water & Wastewater (2005). Method # 2120 C, Color in water by spectrophotometry, single wavelength method 2/3-4. Prep. and Publ. Jointly by Am. Publ. Heath Assoc, Am. Water Works Assoc., Water Env. Fed, 21st Edition. USA.
  • [29] [29] EN ISO 7393-1. Water quality (2000). Determination of free chlorine and total chlorine - Part 1: Titrimetric method using N,N-diethyl-1,4-phenylenediamine.
  • [30] EN ISO 10304-1. Water quality (2009). Determination of dissolved anions by liquid chromatography of ions - Part 1: Determination of bromide, chloride, fluoride, nitrate, nitrite, phosphate and sulphate, 2009.
  • [31] EPA, Measurement of Purgeable Organic Compounds in Water by Capillary Column Gas Chromatography / Mass Spectrometry (1995). Method # 524.2. U.S. Environmental Protection Agency, Revision 4.1.
  • [32] Anonymous (2022). R development core team. R: A language and environment for statistical computing, R foundation for statistical computing, Vienna, Austria. ISBN 3-900051-07-0. https://www.R-project.org/ [accessed 22 03 2022].
  • [33] Park, K., Choi, S., Lee, S., Kweon, J. (2016). Comparison of formation of disinfection by-products by chlorination and ozonation of wastewater effluents and their toxicity to Daphnia magna. Environmental Pollution, 215, 314-321.
  • [34] Stefan, D., Erdelyi, N., Izsak, B., Zaray, G., Vargha, M. (2019). Formation of chlorination by-products in drinking water treatment plants using breakpoint chlorination. Microchemical Journal, 149, 104008.
  • [35] Akbarzadeh, S., Kaefei, R., Hashemi, S., Ramavandi, B. (2016). Data on the relationship between bromide content and the formation potential of THMs, HAAs, and HANs upon chlorination and monochloramination of Karoon River water, Iran. Data in Brief, 8, 415-419.
  • [36] Karaca, H., Velioglu, Y.S. (2009). Effects of some metals and chelating agents on patulin degradation by ozone. Ozone: Science & Engineering, 31, 224-231.
  • [37] Yu, J., Wang, Y., Wang, Q., Wang, Z., Zhang, D. et al. (2020). Implications of bromate depression from H2O2 addition during ozonation of different bromide-bearing source waters. Chemosphere, 252, 126596
Toplam 37 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Gıda Mühendisliği
Bölüm Araştırma Makaleleri
Yazarlar

Yakup Sedat Velioğlu 0000-0002-3281-6229

Rukiye Akdoğan 0000-0002-3362-3007

Zehra Baloğlu 0000-0002-4668-3818

Yayımlanma Tarihi 31 Aralık 2023
Gönderilme Tarihi 9 Ocak 2023
Yayımlandığı Sayı Yıl 2023

Kaynak Göster

APA Velioğlu, Y. S., Akdoğan, R., & Baloğlu, Z. (2023). Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine. Akademik Gıda, 21(4), 333-342. https://doi.org/10.24323/akademik-gida.1422793
AMA Velioğlu YS, Akdoğan R, Baloğlu Z. Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine. Akademik Gıda. Aralık 2023;21(4):333-342. doi:10.24323/akademik-gida.1422793
Chicago Velioğlu, Yakup Sedat, Rukiye Akdoğan, ve Zehra Baloğlu. “Effects of Humic Acid and Bromide on Trihalomethane Formation During Water Disinfection With Chlorine”. Akademik Gıda 21, sy. 4 (Aralık 2023): 333-42. https://doi.org/10.24323/akademik-gida.1422793.
EndNote Velioğlu YS, Akdoğan R, Baloğlu Z (01 Aralık 2023) Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine. Akademik Gıda 21 4 333–342.
IEEE Y. S. Velioğlu, R. Akdoğan, ve Z. Baloğlu, “Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine”, Akademik Gıda, c. 21, sy. 4, ss. 333–342, 2023, doi: 10.24323/akademik-gida.1422793.
ISNAD Velioğlu, Yakup Sedat vd. “Effects of Humic Acid and Bromide on Trihalomethane Formation During Water Disinfection With Chlorine”. Akademik Gıda 21/4 (Aralık 2023), 333-342. https://doi.org/10.24323/akademik-gida.1422793.
JAMA Velioğlu YS, Akdoğan R, Baloğlu Z. Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine. Akademik Gıda. 2023;21:333–342.
MLA Velioğlu, Yakup Sedat vd. “Effects of Humic Acid and Bromide on Trihalomethane Formation During Water Disinfection With Chlorine”. Akademik Gıda, c. 21, sy. 4, 2023, ss. 333-42, doi:10.24323/akademik-gida.1422793.
Vancouver Velioğlu YS, Akdoğan R, Baloğlu Z. Effects of Humic Acid and Bromide on Trihalomethane Formation during Water Disinfection with Chlorine. Akademik Gıda. 2023;21(4):333-42.

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