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Year 2019, Volume: 2 Issue: 1, 13 - 18, 31.03.2019

Abstract

References

  • S. Varol, A. Davraz and E. Varol, "Yeraltı suyu Kimyası ve Sağlığa Etkisinin Tıbbi Jeoloji Açısından Değerlendirilmesi", TAF Preventive Medicine Bulletin, Vol. 7, pp 351–356, 2008.
  • Ü. Şahin, T.Tunç and S. Örs, "Utilization of Wastewater in Terms of Underground Water Pollution", Tarım Bilimleri Araştırma Dergisi, Vol. 4, pp. 33–39, 2011.
  • U. Gebeloğlu, "Arsenic Removal with Electrochemical Wastewater Treatment Process", Gebze Institute of Technology, 2010.
  • H.G. Gorchev and G. Ozolins, "WHO guidelines for drinking-water quality", 2011.
  • R. Singh, S. Singh, P. Parihar, V.P. Singh and S.M. Prasad, "Arsenic contamination, consequences and remediation techniques: A review", Ecotoxicology and Environmental Safety, Vol. 112, pp. 247–270, 2015.
  • A. Ortega, I. Oliva, K.E. Contreras, I. González, M.R. Cruz-Díaz and E.P. Rivero, "Arsenic removal from water by hybrid electro-regenerated anion exchange resin/electrodialysis process", Seperation and Purification Technology, Vol. 184, pp. 319–326, 2017.
  • A.H. Smith, C. Hopenhayn-Rich, M.N. Bates, H.M. Goeden, I. Hertz-Picciotto, H.M. Duggan, R. Wood, M.J. Kosnett and M.T. Smith, "Cancer risks from arsenic in drinking water", Environmental Health Perspectives, Vol. 97, pp. 259–267, 1992.
  • A. Guzmán, J.L. Nava, O. Coreño, I. Rodríguez and S. Gutiérrez, "Arsenic and fluoride removal from groundwater by electrocoagulation using a continuous filter-press reactor", Chemosphere, Vol. 144, pp. 2113–2120, 2016.
  • B.F. Urbano, B.L. Rivas, F. Martinez and S.D. Alexandratos, "Water-insoluble polymer-clay nanocomposite ion exchange resin based on N-methyl-d-glucamine ligand groups for arsenic removal", Reactive and Functional Polymers, Vol. 72, pp. 642–649, 2012.
  • A. Abejon, A. Garea and A. Irabien, "Arsenic removal from drinking water by reverse osmosis: Minimization of costs and energy consumption", Seperation and Purification Technology, Vol. 144, pp. 46–53, 2015.
  • S.-Y. Huang, C.-S. Fan and C.-H. Hou, "Electro-enhanced removal of copper ions from aqueous solutions by capacitive deionization", Journal of Hazardous. Materials. Vol. 278, pp. 8–15, 2014.
  • Y. Chen, L. Peng, Q. Zeng, Y. Yang, M. Lei, H. Song, L. Chai and J. Gu, "Removal of trace Cd(II) from water with the manganese oxides/ACF composite electrode", Clean Technologies and Environmental Policy, Vol. 17, pp. 49–57, 2014
  • A.M. Silva, R.M.F. Lima and V.A. Leão, "Mine water treatment with limestone for sulfate removal", Journal of Hazardous Materials, Vol. 221–222, pp. 45–55, 2012.
  • H. Li, L. Zou, L. Pan and Z. Sun, "Using graphene nano-flakes as electrodes to remove ferric ions by capacitive deionization", Seperation and Purification Technology, Vol. 75, pp. 8–14, 2010.
  • S.J. Seo, H. Jeon, J.K. Lee, G.Y. Kim, D. Park, H. Nojima, J. Lee and S.H. Moon, "Investigation on removal of hardness ions by capacitive deionization (CDI) for water softening applications", Water Research, Vol. 44, pp. 2267–2275, 2010.
  • E. Avraham, M. Noked, A. Soffer and D. Aurbach, "The feasibility of boron removal from water by capacitive deionization", Electrochimica Acta, Vol. 56, pp. 6312–6317, 2011.
  • M. Mossad, W. Zhang and L. Zou, "Using capacitive deionisation for inland brackish groundwater desalination in a remote location", Desalination, Vol. 308, pp. 154–160, 2013.
  • W. Tang, P. Kovalsky, D. He and T.D. Waite, "Fluoride and nitrate removal from brackish groundwaters by batch-mode capacitive deionization", Water Research, Vol. 84, pp. 342–349, 2015.
  • Y.X. Liu, D.X. Yuan, J.M. Yan, Q.L. Li and T. Ouyang, "Electrochemical removal of chromium from aqueous solutions using electrodes of stainless steel nets coated with single wall carbon nanotubes", Journal of Hazardous Materials, Vol. 186, pp. 473–480, 2011.
  • C.S. Fan, S.C. Tseng, K.C. Li and C.H. Hou, "Electro-removal of arsenic(III) and arsenic(V) from aqueous solutions by capacitive deionization", Journal of Hazardous Materials, Vol. 312, pp. 208–215, 2016.
  • Y. Oren, "Capacitive deionization (CDI) for desalination and water treatment - past, present and future (a review)", Desalination, Vol. 228, pp. 10–29, 2008.
  • P. Długołecki, A and Van Der Wal, "Energy recovery in membrane capacitive deionization", Environmental Science and Technology, Vol. 47, pp. 4904–4910, 2013.
  • E. Debik and H. I. Uzun, "Yeraltı Suyu İyonik Kirleticilerin Giderimin Membran Kapasitif Deiyonizasyon Prosesi : Performans Parametrelerinin ve Optimum İşletme Şartlarının Tespiti", ISEM2016, 3rd International Symposium on Environment and Morality, Alanya–Turkey 4-6 November 2016.
  • C.S. Fan, S.Y.H. Liou, and C.H. Hou, "Capacitive deionization of arsenic-contaminated groundwater in a single-pass mode", Chemosphere, Vol. 184, pp. 924–931, 2017.
  • P. Xu, M. Capito, and T.Y. Cath, "Selective removal of arsenic and monovalent ions from brackish water reverse osmosis concentrate", Journal of Hazardous Materials, Vol. 260, pp. 885–891, 2013.
  • H. Saitúa, M. Campderrós, S. Cerutti and A.P. Padilla, "Effect of operating conditions in removal of arsenic from water by nanofiltration membrane", Desalination, Vol. 172, pp. 173–180, 2005.

Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater

Year 2019, Volume: 2 Issue: 1, 13 - 18, 31.03.2019

Abstract

Access to water is a
problem the magnitude of which increases day by day. In addition to water
scarcity, water contamination also plays an important part in the exacerbation
of this problem. Underground and surface waters can be polluted as a result of
human activities as well as natural sources. One of the most commonly found
natural pollutants is arsenic. Risks and effects of arsenic on health make it
necessary to be treated from water. Conventional methods of arsenic removal
make it necessary for new studies to be conducted because of problems such
economical and special equipment needs. The MCDI process stands out with its
advantages such as being economic, flexibly and installation a package process.
In this study, using the optimum conditions which are operating times, flow
rate, current, voltage, number of cycles, previously determined for Voltea
brand MCDI, the removal of arsenic from the wastewater produced by Emet Bor
Operation Directorate Espey Open Quarry and Concentrator Facility, Hisarcik
Open Quarry and Concentrator Facility and Boric Acid Production Facility during
their activities has been studied. The removal efficiency of the MCDI process
for arsenic was 94%.

References

  • S. Varol, A. Davraz and E. Varol, "Yeraltı suyu Kimyası ve Sağlığa Etkisinin Tıbbi Jeoloji Açısından Değerlendirilmesi", TAF Preventive Medicine Bulletin, Vol. 7, pp 351–356, 2008.
  • Ü. Şahin, T.Tunç and S. Örs, "Utilization of Wastewater in Terms of Underground Water Pollution", Tarım Bilimleri Araştırma Dergisi, Vol. 4, pp. 33–39, 2011.
  • U. Gebeloğlu, "Arsenic Removal with Electrochemical Wastewater Treatment Process", Gebze Institute of Technology, 2010.
  • H.G. Gorchev and G. Ozolins, "WHO guidelines for drinking-water quality", 2011.
  • R. Singh, S. Singh, P. Parihar, V.P. Singh and S.M. Prasad, "Arsenic contamination, consequences and remediation techniques: A review", Ecotoxicology and Environmental Safety, Vol. 112, pp. 247–270, 2015.
  • A. Ortega, I. Oliva, K.E. Contreras, I. González, M.R. Cruz-Díaz and E.P. Rivero, "Arsenic removal from water by hybrid electro-regenerated anion exchange resin/electrodialysis process", Seperation and Purification Technology, Vol. 184, pp. 319–326, 2017.
  • A.H. Smith, C. Hopenhayn-Rich, M.N. Bates, H.M. Goeden, I. Hertz-Picciotto, H.M. Duggan, R. Wood, M.J. Kosnett and M.T. Smith, "Cancer risks from arsenic in drinking water", Environmental Health Perspectives, Vol. 97, pp. 259–267, 1992.
  • A. Guzmán, J.L. Nava, O. Coreño, I. Rodríguez and S. Gutiérrez, "Arsenic and fluoride removal from groundwater by electrocoagulation using a continuous filter-press reactor", Chemosphere, Vol. 144, pp. 2113–2120, 2016.
  • B.F. Urbano, B.L. Rivas, F. Martinez and S.D. Alexandratos, "Water-insoluble polymer-clay nanocomposite ion exchange resin based on N-methyl-d-glucamine ligand groups for arsenic removal", Reactive and Functional Polymers, Vol. 72, pp. 642–649, 2012.
  • A. Abejon, A. Garea and A. Irabien, "Arsenic removal from drinking water by reverse osmosis: Minimization of costs and energy consumption", Seperation and Purification Technology, Vol. 144, pp. 46–53, 2015.
  • S.-Y. Huang, C.-S. Fan and C.-H. Hou, "Electro-enhanced removal of copper ions from aqueous solutions by capacitive deionization", Journal of Hazardous. Materials. Vol. 278, pp. 8–15, 2014.
  • Y. Chen, L. Peng, Q. Zeng, Y. Yang, M. Lei, H. Song, L. Chai and J. Gu, "Removal of trace Cd(II) from water with the manganese oxides/ACF composite electrode", Clean Technologies and Environmental Policy, Vol. 17, pp. 49–57, 2014
  • A.M. Silva, R.M.F. Lima and V.A. Leão, "Mine water treatment with limestone for sulfate removal", Journal of Hazardous Materials, Vol. 221–222, pp. 45–55, 2012.
  • H. Li, L. Zou, L. Pan and Z. Sun, "Using graphene nano-flakes as electrodes to remove ferric ions by capacitive deionization", Seperation and Purification Technology, Vol. 75, pp. 8–14, 2010.
  • S.J. Seo, H. Jeon, J.K. Lee, G.Y. Kim, D. Park, H. Nojima, J. Lee and S.H. Moon, "Investigation on removal of hardness ions by capacitive deionization (CDI) for water softening applications", Water Research, Vol. 44, pp. 2267–2275, 2010.
  • E. Avraham, M. Noked, A. Soffer and D. Aurbach, "The feasibility of boron removal from water by capacitive deionization", Electrochimica Acta, Vol. 56, pp. 6312–6317, 2011.
  • M. Mossad, W. Zhang and L. Zou, "Using capacitive deionisation for inland brackish groundwater desalination in a remote location", Desalination, Vol. 308, pp. 154–160, 2013.
  • W. Tang, P. Kovalsky, D. He and T.D. Waite, "Fluoride and nitrate removal from brackish groundwaters by batch-mode capacitive deionization", Water Research, Vol. 84, pp. 342–349, 2015.
  • Y.X. Liu, D.X. Yuan, J.M. Yan, Q.L. Li and T. Ouyang, "Electrochemical removal of chromium from aqueous solutions using electrodes of stainless steel nets coated with single wall carbon nanotubes", Journal of Hazardous Materials, Vol. 186, pp. 473–480, 2011.
  • C.S. Fan, S.C. Tseng, K.C. Li and C.H. Hou, "Electro-removal of arsenic(III) and arsenic(V) from aqueous solutions by capacitive deionization", Journal of Hazardous Materials, Vol. 312, pp. 208–215, 2016.
  • Y. Oren, "Capacitive deionization (CDI) for desalination and water treatment - past, present and future (a review)", Desalination, Vol. 228, pp. 10–29, 2008.
  • P. Długołecki, A and Van Der Wal, "Energy recovery in membrane capacitive deionization", Environmental Science and Technology, Vol. 47, pp. 4904–4910, 2013.
  • E. Debik and H. I. Uzun, "Yeraltı Suyu İyonik Kirleticilerin Giderimin Membran Kapasitif Deiyonizasyon Prosesi : Performans Parametrelerinin ve Optimum İşletme Şartlarının Tespiti", ISEM2016, 3rd International Symposium on Environment and Morality, Alanya–Turkey 4-6 November 2016.
  • C.S. Fan, S.Y.H. Liou, and C.H. Hou, "Capacitive deionization of arsenic-contaminated groundwater in a single-pass mode", Chemosphere, Vol. 184, pp. 924–931, 2017.
  • P. Xu, M. Capito, and T.Y. Cath, "Selective removal of arsenic and monovalent ions from brackish water reverse osmosis concentrate", Journal of Hazardous Materials, Vol. 260, pp. 885–891, 2013.
  • H. Saitúa, M. Campderrós, S. Cerutti and A.P. Padilla, "Effect of operating conditions in removal of arsenic from water by nanofiltration membrane", Desalination, Vol. 172, pp. 173–180, 2005.
There are 26 citations in total.

Details

Primary Language English
Subjects Environmental Engineering
Journal Section Research Articles
Authors

Halil İbrahim Uzun 0000-0001-6158-743X

Eyüp Debik 0000-0003-1864-4253

Publication Date March 31, 2019
Submission Date July 2, 2018
Acceptance Date December 20, 2018
Published in Issue Year 2019 Volume: 2 Issue: 1

Cite

APA Uzun, H. İ., & Debik, E. (2019). Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater. Environmental Research and Technology, 2(1), 13-18.
AMA Uzun Hİ, Debik E. Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater. ERT. March 2019;2(1):13-18.
Chicago Uzun, Halil İbrahim, and Eyüp Debik. “Detection of Effective Parameters in Arsenic Removal With Capacitive Deionization Process and Arsenic Removal from Wastewater”. Environmental Research and Technology 2, no. 1 (March 2019): 13-18.
EndNote Uzun Hİ, Debik E (March 1, 2019) Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater. Environmental Research and Technology 2 1 13–18.
IEEE H. İ. Uzun and E. Debik, “Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater”, ERT, vol. 2, no. 1, pp. 13–18, 2019.
ISNAD Uzun, Halil İbrahim - Debik, Eyüp. “Detection of Effective Parameters in Arsenic Removal With Capacitive Deionization Process and Arsenic Removal from Wastewater”. Environmental Research and Technology 2/1 (March 2019), 13-18.
JAMA Uzun Hİ, Debik E. Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater. ERT. 2019;2:13–18.
MLA Uzun, Halil İbrahim and Eyüp Debik. “Detection of Effective Parameters in Arsenic Removal With Capacitive Deionization Process and Arsenic Removal from Wastewater”. Environmental Research and Technology, vol. 2, no. 1, 2019, pp. 13-18.
Vancouver Uzun Hİ, Debik E. Detection of effective parameters in arsenic removal with capacitive deionization process and arsenic removal from wastewater. ERT. 2019;2(1):13-8.