Research Article
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Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin

Year 2023, , 177 - 189, 25.12.2023
https://doi.org/10.51354/mjen.1260477

Abstract

Hazelnut shell biosorbent immobilized on Amberlite XAD-4 polymer resin as solid phase extraction method was developed and used for preconcentration of Cu(II) and Cd(II) ions from aqueous solutions. Concentrations of analytes in solutions were determined by Flame Atomic Absorption Spectrometry after extraction with column technique. Functional groups of nutshell biosorbent immobilized on resin were characterized by Fourier transform infrared spectrometry. Optimized critical parameters for preconcentration of Cu2+ and Cd2+ ions from sample solutions with nutshell immobilized on the resin were the pH value of solution, type of eluent solutions, the flow rate of sample solution, quantities of nutshell biosorbent, Amberlite XAD-4 resin, and enrichment factors, respectively. Detection limits of Cu2+ and Cd2+ ions found were 0.29 μg L-1 and 0.25 μg L-1, respectively. The method proposed was applied for determinations of Cu2+ and Cd2+ ions in standard reference material (BCR-670 aquatic plant sample) for accuracy and applied to real water samples such as wastewater and Van lake water. At the 95% confidence level, relative standard deviations (RSDs) were found as 1.44% for Cd2+ and 1.21% for Cu2+ ions with three replicate measurements.

Project Number

2015-SİÜFEB-34

References

  • [1]. Bilgin E., Erol K., Köse K., Köse D. A., "Use of nicotinamide decorated polymeric cryogels as heavy metal sweeper", Environmental Science and Pollution Research, 25(27), (2018), 27614-27627.
  • [2]. Ozay H., Gungor Z., Yilmaz B., Ilgin P., Ozay O., "Dual use of colorimetric sensor and selective copper removal from aqueous media with novel p(HEMA-co-TACYC) hydrogels: Cyclen derivative as both monomer and crosslinker", Journal of Hazardous Materials, 389, (2020), 121848.
  • [3]. Kumar M., Pakshirajan K., "Continuous removal and recovery of metals from wastewater using inverse fluidized bed sulfidogenic bioreactor", Journal of Cleaner Production, 284, (2021), 124769.
  • [4]. Lellala K., "Sulphur Embedded On In-Situ Carbon Nanodisc Decorated On Graphene Sheets For Efficient Photocatalytic Activity And Capacitive Deionization Method For Heavy Metal Removal", Journal of Materials Research and Technology, 13, (2021), 1555-1566.
  • [5]. Shrestha R., Ban S., Devkota S., Sharma S., Joshi R., Tiwari A. P., Kim H. Y., Joshi M. K., "Technological Trends in Heavy Metals Removal from Industrial Wastewater: A Review", Journal of Environmental Chemical Engineering, 9, (2021), 105688.
  • [6]. Gürbüz F., Akpınar Ş., Özcan S., Acet, Ö, Odabaşı M., "Reducing arsenic and groundwater contaminants down to safe level for drinking purposes via Fe3+-attached hybrid column", Environmental Monitoring and Assessment 191(722), (2019), 1-14.
  • [7]. Duarte-Nass C., Rebolledo K., Valenzuela T., Kopp M., Jeison D., Rivas M., Azócar L., Torres-Aravena Á., Ciudad G., "Application of microbe-induced carbonate precipitation for copper removal from copper-enriched waters: Challenges to future industrial application", Journal of Environmental Management, 256, (2020), 109938.
  • [8]. Yan Y., Liang X., Ma J., Shen J., "Rapid removal of copper from wastewater by Fe-based amorphous alloy", Intermetallics, 124, (2020), 106849.
  • [9]. Elvan H., Ozdes D., Duran C., Sahin D., Tufekci M., Bahadir Z., "Separation and preconcentration of copper in environmental samples on Amberlite XAD-8 resin after complexation with a carbothioamide derivative", Química Nova, 36(6), (2013), 831-835.
  • [10]. Enez B., Varhan Oral E., Aguloglu Fincan S., Ziyadanogullari B., "Comparison of Methods for the Preconcentration of Cadmium(II) Using Amberlite XAD-16 Resin Modified with Anoxybacillus caldiproteolyticus and Geobacillus stearothermophilus as Novel Biosorbents", Analytical Letters, 53(2), (2020), 322-342.
  • [11]. Jayakumar V., Govindaradjane S., Senthilkumar P., Rajamohan N., Rajasimman M., "Sustainable removal of cadmium from contaminated water using green alga–Optimization, characterization and modeling studies", Environmental Research, 199, (2021), 111364.
  • [12]. Chatterjee S., Sivareddy I., De S., "Adsorptive removal of potentially toxic metals (cadmium, copper, nickel and zinc) by chemically treated laterite: Single and multicomponent batch and column study", Journal of Environmental Chemical Engineering, 5(4), (2017), 3273-3289.
  • [13]. Sun H., Xia N., Liu Z., Kong F., Wang S., "Removal of copper and cadmium ions from alkaline solutions using chitosan-tannin functional paper materials as adsorbent", Chemosphere, 236, (2019), 124370.
  • [14]. Jiang Q., Song X., Liu J., Shao Y., He W., Feng Y., "In-situ enrichment and removal of Cu(II) and Cd(II) from low-strength wastewater by a novel microbial metals enrichment and recovery cell (MMERC)", Journal of Power Sources, 451, (2020), 227627.
  • [15]. Bandara T., Xu J., Potter I. D., Franks A., Chathurika J., Tang C., "Mechanisms for the removal of Cd(II) and Cu(II) from aqueous solution and mine water by biochars derived from agricultural wastes", Chemosphere, 254, (2020), 126745.
  • [16]. Arancibia-Miranda N., Manquián-Cerda K., Pizarro C., Maldonado T., Suazo-Hernández J., Escudey M., Bolan N., Sarkar B., "Mechanistic insights into simultaneous removal of copper, cadmium and arsenic from water by iron oxide-functionalized magnetic imogolite nanocomposites", Journal of Hazardous Materials, 398, (2020), 122940.
  • [17]. Ma J., Huang W., Zhang X., Li Y., Wang N., "The utilization of lobster shell to prepare low-cost biochar for high-efficient removal of copper and cadmium from aqueous: Sorption properties and mechanisms", Journal of Environmental Chemical Engineering, 9(1), (2021), 104703.
  • [18]. Gendy E. A., Ifthikar J., Ali J., Oyekunle D. T., Elkhlifia Z., Shahib I. I., Khodair A. I., Chen Z., "Removal of heavy metals by Covalent Organic Frameworks (COFs): A review on its mechanism and adsorption properties", Journal of Environmental Chemical Engineering, (2021), 105687.
  • [19]. Ru J., Wang X., Wang F., Cui X., Du X., Lu X., "UiO series of metal-organic frameworks composites as advanced sorbents for the removal of heavy metal ions: Synthesis, applications and adsorption mechanism", Ecotoxicology and Environmental Safety, 208, (2021), 111577.
  • [20]. Erol B., Erol K., Gökmeşe E., "The effect of the chelator characteristics on insulin adsorption in immobilized metal affinity chromatography", Process Biochemistry, 83, (2019), 104-113.
  • [21]. Erol K., Yıldız E., Alacabey İ., Karabörk M., Uzun L., "Magnetic diatomite for pesticide removal from aqueous solution via hydrophobic interactions", Environmental Science and Pollution Research, 26(32), (2019), 33631-33641.
  • [22]. Zhang Y., Cheng Q., Wang C., Li H., Han X., Fan Z., Su G., Pan D., Li Z., "Research progress of adsorption and removal of heavy metals by chitosan and its derivatives: A review", Chemosphere, 279, (2021), 130927.
  • [23]. Gürbüz F., Özcan, A., Çiftci H., Acet Ö., Odabaşı M., "Treatment of textile effluents through bio-composite column: decolorization and COD reduction", International Journal of Environmental Science and Technology, 16, (2019), 8653–8662.
  • [24]. Lee L. Y., Gan S., Tan M. S. Y., Lim S. S., Lee X. J., Lam Y. F., "Effective removal of Acid Blue 113 dye using overripe Cucumis sativus peel as an eco-friendly biosorbent from agricultural residue", Journal of Cleaner Production, 113, (2016), 194-203.
  • [25]. Singh S., Parveen N., Gupta H., "Adsorptive decontamination of rhodamine-B from water using banana peel powder: a biosorbent", Environmental Technology & Innovation, 12, (2018), 189-195.
  • [26]. Rehman R., Farooq S., Mahmud T., "Use of agro-waste Musa acuminata and Solanum tuberosum peels for economical sorptive removal of emerald green dye in ecofriendly way", Journal of Cleaner Production, 206, (2019), 819-826.
  • [27]. Ahmad A., Siddique J. A., Laskar M. A., Kumar R., Mohd-Setapar S. H., Khatoon A., Shiekh R. A., "New generation Amberlite XAD resin for the removal of metal ions: A review", Journal of Environmental Sciences, 31, (2015), 104-123.
  • [28]. Elbadawy H. A., Abdel-Salam A. H., Khalil T. E., "The impact of an Amberlite XAD-16-based chelating resin for the removal of aqueous Cd(II) and Pb(II) ions", Microchemical Journal, 165, (2021), 106097.
  • [29]. Varhan Oral E., Özdemir S., Dolak I., Okumus V., Dundar A., Ziyadanogullari B., Aksoy Z., Onat R., "Anoxybacillus sp. SO B1–immobilized Amberlite XAD-16 for solid-phase preconcentration of Cu(II) and Pb(II) and their determinations by flame atomic absorption spectrometry", Bioremediation Journal, 19(2), (2015), 139-150.
  • [30]. ul Hoque M. I., Chowdhury D. A., Holze R., Chowdhury A. N., Azam M. S., "Modification of Amberlite XAD-4 resin with 1, 8-diaminonaphthalene for solid phase extraction of copper, cadmium and lead, and its application to determination of these metals in dairy cow’s milk", Journal of Environmental Chemical Engineering, 3(2), (2015), 831-842.
  • [31]. Ghaedi M., Montazerozohori M., Hekmati A., Roosta M., "Solid phase extraction of heavy metals on chemically modified silica-gel with 2-(3-silylpropylimino) methyl)-5-bromophenol in food samples", International Journal of Environmental Analytical Chemistry, 93(8), (2013), 843-857.
  • [32]. Dogan S., Dinçer Kaya F. N., Atakol O., "Enrichment of copper and nickel with solid phase extraction using multiwalled carbon nanotubes modified with Schiff bases", International Journal of Environmental Analytical Chemistry, 95(8), (2015), 698-712.
  • [33]. Varhan Oral E., Dolak I., Temel H., Ziyadanogullari B., "Preconcentration and determination of copper and cadmium ions with 1, 6-bis (2-carboxy aldehyde phenoxy) butane functionalized Amberlite XAD-16 by flame atomic absorption spectrometry", Journal of Hazardous Materials, 186(1), (2011), 724-730.
  • [34]. Amin A. S., Moalla S. M., Khalil M. A., "Solid Phase Extraction Utilization for Colorimetric Determination of Zinc in Waters, Food, Milk, and Biological Samples", International Journal of Analytical and Bioanalytical Methods, 1(006), (2019), 1-8.
  • [35]. Özdemir S., Kılınç E., Fatih S., "A novel biosorbent for preconcentrations of Co(II) and Hg(II) in real samples", Scientific Reports, 10(1), (2020), 1-9.
  • [36]. Barquilha C. E., Cossich E. S., Tavares C. R., da Silva E. A., "Biosorption of nickel(II) and copper(II) ions from synthetic and real effluents by alginate-based biosorbent produced from seaweed Sargassum sp", Environmental Science and Pollution Research, 26(11), (2019), 11100-11112.
  • [37]. de Freitas G. R., da Silva M. G. C., Vieira M. G. A., "Biosorption technology for removal of toxic metals: a review of commercial biosorbents and patents", Environmental Science and Pollution Research, 26(19), (2019), 19097-19118.
  • [38]. Okumuş V., Özdemir S., Kılınç E., Dündar A., Yüksel U., Baysal Z., "Preconcentration with Bacillus subtilis–immobilized amberlite XAD-16: determination of Cu2+ and Ni2+ in river, soil, and vegetable samples", Bioremediation Journal, 19(1), (2015), 47-55.
  • [39]. Baytak S., Channa A. M., Çamuroğlu E., "Mucor pusillus immobilized Amberlite XAD-4 biocomposites for preconcentration of heavy metal ions by solid-phase extraction method", Journal of Analytical Science and Technology, 9(1), (2018), 1-6.
  • [40]. Özdemir S., Okumuş V., Kılınç E., Bilgetekin H., Dündar A., Ziyadanogˇulları B., "Pleurotus eryngii immobilized Amberlite XAD-16 as a solid-phase biosorbent for preconcentrations of Cd2+ and Co2+ and their determination by ICP-OES", Talanta, 99, (2012), 502-506.
  • [41]. Jagung P. T., "Removal of Zn(II), Cd(II) and Mn(II) from aqueous solutions by adsorption on maize stalks", Malaysian Journal of Analytical Sciences, 15(1), (2011), 8-21.
  • [42]. Özdemir S., Okumuş V., Dündar A., Kılınç E., "The use of fungal biomass Agaricus bisporus immobilized on amberlite XAD-4 resin for the solid-phase preconcentration of Thorium", Bioremediation Journal, 18(1), (2014), 38-45.
  • [43]. García A. V., Santonja M. R., Sanahuja A. B., Selva M. d. C. G., "Characterization and degradation characteristics of poly(ε-caprolactone)-based composites reinforced with almond skin residues", Polymer Degradation and Stability, 108, (2014), 269-279.
  • [44]. Yahaya Y. A., Don M. M., "Pycnoporus sanguineus as potential biosorbent for heavy metal removal from aqueous solution: A review", Journal of Physical Science, 25(1), (2014), 1.
  • [45]. Ziaei E., Mehdinia A., Jabbari A., "A novel hierarchical nanobiocomposite of graphene oxide–magnetic chitosan grafted with mercapto as a solid phase extraction sorbent for the determination of mercury ions in environmental water samples", Analytica Chimica Acta, 850, (2014), 49-56.
  • [46]. Özdemir S., Kilinc E., Celik K. S., Okumus V., Soylak M., "Simultaneous preconcentrations of Co2+, Cr6+, Hg2+ and Pb2+ ions by Bacillus altitudinis immobilized nanodiamond prior to their determinations in food samples by ICP-OES", Food Chemistry, 215, (2017), 447-453.
  • [47]. Kara D., Fisher A., Hill S. J., "Preconcentration and determination of trace elements with 2,6-diacetylpyridine functionalized Amberlite XAD-4 by flow injection and atomic spectroscopy", Analyst, 130(11), (2005), 1518-1523.
  • [48]. Karadaş C., Kara D., "On-line preconcentration and determination of trace elements in waters and reference cereal materials by flow injection–FAAS using newly synthesized 8-hydroxy-2-quinoline carboxaldehyde functionalized Amberlite XAD-4", Journal of Food Composition and Analysis, 32(1), (2013), 90-98.
  • [49]. Karadaş C., Turhan O., Kara D., "Synthesis and application of a new functionalized resin for use in an on-line, solid phase extraction system for the determination of trace elements in waters and reference cereal materials by flame atomic absorption spectrometry", Food Chemistry, 141(2), (2013), 655-661.
Year 2023, , 177 - 189, 25.12.2023
https://doi.org/10.51354/mjen.1260477

Abstract

Supporting Institution

Siirt Üniversitesi

Project Number

2015-SİÜFEB-34

Thanks

Siirt Üniversitesi Bilimsel Araştırma Projeleri'ne desteklerinden ötürü teşekkür ederiz.

References

  • [1]. Bilgin E., Erol K., Köse K., Köse D. A., "Use of nicotinamide decorated polymeric cryogels as heavy metal sweeper", Environmental Science and Pollution Research, 25(27), (2018), 27614-27627.
  • [2]. Ozay H., Gungor Z., Yilmaz B., Ilgin P., Ozay O., "Dual use of colorimetric sensor and selective copper removal from aqueous media with novel p(HEMA-co-TACYC) hydrogels: Cyclen derivative as both monomer and crosslinker", Journal of Hazardous Materials, 389, (2020), 121848.
  • [3]. Kumar M., Pakshirajan K., "Continuous removal and recovery of metals from wastewater using inverse fluidized bed sulfidogenic bioreactor", Journal of Cleaner Production, 284, (2021), 124769.
  • [4]. Lellala K., "Sulphur Embedded On In-Situ Carbon Nanodisc Decorated On Graphene Sheets For Efficient Photocatalytic Activity And Capacitive Deionization Method For Heavy Metal Removal", Journal of Materials Research and Technology, 13, (2021), 1555-1566.
  • [5]. Shrestha R., Ban S., Devkota S., Sharma S., Joshi R., Tiwari A. P., Kim H. Y., Joshi M. K., "Technological Trends in Heavy Metals Removal from Industrial Wastewater: A Review", Journal of Environmental Chemical Engineering, 9, (2021), 105688.
  • [6]. Gürbüz F., Akpınar Ş., Özcan S., Acet, Ö, Odabaşı M., "Reducing arsenic and groundwater contaminants down to safe level for drinking purposes via Fe3+-attached hybrid column", Environmental Monitoring and Assessment 191(722), (2019), 1-14.
  • [7]. Duarte-Nass C., Rebolledo K., Valenzuela T., Kopp M., Jeison D., Rivas M., Azócar L., Torres-Aravena Á., Ciudad G., "Application of microbe-induced carbonate precipitation for copper removal from copper-enriched waters: Challenges to future industrial application", Journal of Environmental Management, 256, (2020), 109938.
  • [8]. Yan Y., Liang X., Ma J., Shen J., "Rapid removal of copper from wastewater by Fe-based amorphous alloy", Intermetallics, 124, (2020), 106849.
  • [9]. Elvan H., Ozdes D., Duran C., Sahin D., Tufekci M., Bahadir Z., "Separation and preconcentration of copper in environmental samples on Amberlite XAD-8 resin after complexation with a carbothioamide derivative", Química Nova, 36(6), (2013), 831-835.
  • [10]. Enez B., Varhan Oral E., Aguloglu Fincan S., Ziyadanogullari B., "Comparison of Methods for the Preconcentration of Cadmium(II) Using Amberlite XAD-16 Resin Modified with Anoxybacillus caldiproteolyticus and Geobacillus stearothermophilus as Novel Biosorbents", Analytical Letters, 53(2), (2020), 322-342.
  • [11]. Jayakumar V., Govindaradjane S., Senthilkumar P., Rajamohan N., Rajasimman M., "Sustainable removal of cadmium from contaminated water using green alga–Optimization, characterization and modeling studies", Environmental Research, 199, (2021), 111364.
  • [12]. Chatterjee S., Sivareddy I., De S., "Adsorptive removal of potentially toxic metals (cadmium, copper, nickel and zinc) by chemically treated laterite: Single and multicomponent batch and column study", Journal of Environmental Chemical Engineering, 5(4), (2017), 3273-3289.
  • [13]. Sun H., Xia N., Liu Z., Kong F., Wang S., "Removal of copper and cadmium ions from alkaline solutions using chitosan-tannin functional paper materials as adsorbent", Chemosphere, 236, (2019), 124370.
  • [14]. Jiang Q., Song X., Liu J., Shao Y., He W., Feng Y., "In-situ enrichment and removal of Cu(II) and Cd(II) from low-strength wastewater by a novel microbial metals enrichment and recovery cell (MMERC)", Journal of Power Sources, 451, (2020), 227627.
  • [15]. Bandara T., Xu J., Potter I. D., Franks A., Chathurika J., Tang C., "Mechanisms for the removal of Cd(II) and Cu(II) from aqueous solution and mine water by biochars derived from agricultural wastes", Chemosphere, 254, (2020), 126745.
  • [16]. Arancibia-Miranda N., Manquián-Cerda K., Pizarro C., Maldonado T., Suazo-Hernández J., Escudey M., Bolan N., Sarkar B., "Mechanistic insights into simultaneous removal of copper, cadmium and arsenic from water by iron oxide-functionalized magnetic imogolite nanocomposites", Journal of Hazardous Materials, 398, (2020), 122940.
  • [17]. Ma J., Huang W., Zhang X., Li Y., Wang N., "The utilization of lobster shell to prepare low-cost biochar for high-efficient removal of copper and cadmium from aqueous: Sorption properties and mechanisms", Journal of Environmental Chemical Engineering, 9(1), (2021), 104703.
  • [18]. Gendy E. A., Ifthikar J., Ali J., Oyekunle D. T., Elkhlifia Z., Shahib I. I., Khodair A. I., Chen Z., "Removal of heavy metals by Covalent Organic Frameworks (COFs): A review on its mechanism and adsorption properties", Journal of Environmental Chemical Engineering, (2021), 105687.
  • [19]. Ru J., Wang X., Wang F., Cui X., Du X., Lu X., "UiO series of metal-organic frameworks composites as advanced sorbents for the removal of heavy metal ions: Synthesis, applications and adsorption mechanism", Ecotoxicology and Environmental Safety, 208, (2021), 111577.
  • [20]. Erol B., Erol K., Gökmeşe E., "The effect of the chelator characteristics on insulin adsorption in immobilized metal affinity chromatography", Process Biochemistry, 83, (2019), 104-113.
  • [21]. Erol K., Yıldız E., Alacabey İ., Karabörk M., Uzun L., "Magnetic diatomite for pesticide removal from aqueous solution via hydrophobic interactions", Environmental Science and Pollution Research, 26(32), (2019), 33631-33641.
  • [22]. Zhang Y., Cheng Q., Wang C., Li H., Han X., Fan Z., Su G., Pan D., Li Z., "Research progress of adsorption and removal of heavy metals by chitosan and its derivatives: A review", Chemosphere, 279, (2021), 130927.
  • [23]. Gürbüz F., Özcan, A., Çiftci H., Acet Ö., Odabaşı M., "Treatment of textile effluents through bio-composite column: decolorization and COD reduction", International Journal of Environmental Science and Technology, 16, (2019), 8653–8662.
  • [24]. Lee L. Y., Gan S., Tan M. S. Y., Lim S. S., Lee X. J., Lam Y. F., "Effective removal of Acid Blue 113 dye using overripe Cucumis sativus peel as an eco-friendly biosorbent from agricultural residue", Journal of Cleaner Production, 113, (2016), 194-203.
  • [25]. Singh S., Parveen N., Gupta H., "Adsorptive decontamination of rhodamine-B from water using banana peel powder: a biosorbent", Environmental Technology & Innovation, 12, (2018), 189-195.
  • [26]. Rehman R., Farooq S., Mahmud T., "Use of agro-waste Musa acuminata and Solanum tuberosum peels for economical sorptive removal of emerald green dye in ecofriendly way", Journal of Cleaner Production, 206, (2019), 819-826.
  • [27]. Ahmad A., Siddique J. A., Laskar M. A., Kumar R., Mohd-Setapar S. H., Khatoon A., Shiekh R. A., "New generation Amberlite XAD resin for the removal of metal ions: A review", Journal of Environmental Sciences, 31, (2015), 104-123.
  • [28]. Elbadawy H. A., Abdel-Salam A. H., Khalil T. E., "The impact of an Amberlite XAD-16-based chelating resin for the removal of aqueous Cd(II) and Pb(II) ions", Microchemical Journal, 165, (2021), 106097.
  • [29]. Varhan Oral E., Özdemir S., Dolak I., Okumus V., Dundar A., Ziyadanogullari B., Aksoy Z., Onat R., "Anoxybacillus sp. SO B1–immobilized Amberlite XAD-16 for solid-phase preconcentration of Cu(II) and Pb(II) and their determinations by flame atomic absorption spectrometry", Bioremediation Journal, 19(2), (2015), 139-150.
  • [30]. ul Hoque M. I., Chowdhury D. A., Holze R., Chowdhury A. N., Azam M. S., "Modification of Amberlite XAD-4 resin with 1, 8-diaminonaphthalene for solid phase extraction of copper, cadmium and lead, and its application to determination of these metals in dairy cow’s milk", Journal of Environmental Chemical Engineering, 3(2), (2015), 831-842.
  • [31]. Ghaedi M., Montazerozohori M., Hekmati A., Roosta M., "Solid phase extraction of heavy metals on chemically modified silica-gel with 2-(3-silylpropylimino) methyl)-5-bromophenol in food samples", International Journal of Environmental Analytical Chemistry, 93(8), (2013), 843-857.
  • [32]. Dogan S., Dinçer Kaya F. N., Atakol O., "Enrichment of copper and nickel with solid phase extraction using multiwalled carbon nanotubes modified with Schiff bases", International Journal of Environmental Analytical Chemistry, 95(8), (2015), 698-712.
  • [33]. Varhan Oral E., Dolak I., Temel H., Ziyadanogullari B., "Preconcentration and determination of copper and cadmium ions with 1, 6-bis (2-carboxy aldehyde phenoxy) butane functionalized Amberlite XAD-16 by flame atomic absorption spectrometry", Journal of Hazardous Materials, 186(1), (2011), 724-730.
  • [34]. Amin A. S., Moalla S. M., Khalil M. A., "Solid Phase Extraction Utilization for Colorimetric Determination of Zinc in Waters, Food, Milk, and Biological Samples", International Journal of Analytical and Bioanalytical Methods, 1(006), (2019), 1-8.
  • [35]. Özdemir S., Kılınç E., Fatih S., "A novel biosorbent for preconcentrations of Co(II) and Hg(II) in real samples", Scientific Reports, 10(1), (2020), 1-9.
  • [36]. Barquilha C. E., Cossich E. S., Tavares C. R., da Silva E. A., "Biosorption of nickel(II) and copper(II) ions from synthetic and real effluents by alginate-based biosorbent produced from seaweed Sargassum sp", Environmental Science and Pollution Research, 26(11), (2019), 11100-11112.
  • [37]. de Freitas G. R., da Silva M. G. C., Vieira M. G. A., "Biosorption technology for removal of toxic metals: a review of commercial biosorbents and patents", Environmental Science and Pollution Research, 26(19), (2019), 19097-19118.
  • [38]. Okumuş V., Özdemir S., Kılınç E., Dündar A., Yüksel U., Baysal Z., "Preconcentration with Bacillus subtilis–immobilized amberlite XAD-16: determination of Cu2+ and Ni2+ in river, soil, and vegetable samples", Bioremediation Journal, 19(1), (2015), 47-55.
  • [39]. Baytak S., Channa A. M., Çamuroğlu E., "Mucor pusillus immobilized Amberlite XAD-4 biocomposites for preconcentration of heavy metal ions by solid-phase extraction method", Journal of Analytical Science and Technology, 9(1), (2018), 1-6.
  • [40]. Özdemir S., Okumuş V., Kılınç E., Bilgetekin H., Dündar A., Ziyadanogˇulları B., "Pleurotus eryngii immobilized Amberlite XAD-16 as a solid-phase biosorbent for preconcentrations of Cd2+ and Co2+ and their determination by ICP-OES", Talanta, 99, (2012), 502-506.
  • [41]. Jagung P. T., "Removal of Zn(II), Cd(II) and Mn(II) from aqueous solutions by adsorption on maize stalks", Malaysian Journal of Analytical Sciences, 15(1), (2011), 8-21.
  • [42]. Özdemir S., Okumuş V., Dündar A., Kılınç E., "The use of fungal biomass Agaricus bisporus immobilized on amberlite XAD-4 resin for the solid-phase preconcentration of Thorium", Bioremediation Journal, 18(1), (2014), 38-45.
  • [43]. García A. V., Santonja M. R., Sanahuja A. B., Selva M. d. C. G., "Characterization and degradation characteristics of poly(ε-caprolactone)-based composites reinforced with almond skin residues", Polymer Degradation and Stability, 108, (2014), 269-279.
  • [44]. Yahaya Y. A., Don M. M., "Pycnoporus sanguineus as potential biosorbent for heavy metal removal from aqueous solution: A review", Journal of Physical Science, 25(1), (2014), 1.
  • [45]. Ziaei E., Mehdinia A., Jabbari A., "A novel hierarchical nanobiocomposite of graphene oxide–magnetic chitosan grafted with mercapto as a solid phase extraction sorbent for the determination of mercury ions in environmental water samples", Analytica Chimica Acta, 850, (2014), 49-56.
  • [46]. Özdemir S., Kilinc E., Celik K. S., Okumus V., Soylak M., "Simultaneous preconcentrations of Co2+, Cr6+, Hg2+ and Pb2+ ions by Bacillus altitudinis immobilized nanodiamond prior to their determinations in food samples by ICP-OES", Food Chemistry, 215, (2017), 447-453.
  • [47]. Kara D., Fisher A., Hill S. J., "Preconcentration and determination of trace elements with 2,6-diacetylpyridine functionalized Amberlite XAD-4 by flow injection and atomic spectroscopy", Analyst, 130(11), (2005), 1518-1523.
  • [48]. Karadaş C., Kara D., "On-line preconcentration and determination of trace elements in waters and reference cereal materials by flow injection–FAAS using newly synthesized 8-hydroxy-2-quinoline carboxaldehyde functionalized Amberlite XAD-4", Journal of Food Composition and Analysis, 32(1), (2013), 90-98.
  • [49]. Karadaş C., Turhan O., Kara D., "Synthesis and application of a new functionalized resin for use in an on-line, solid phase extraction system for the determination of trace elements in waters and reference cereal materials by flame atomic absorption spectrometry", Food Chemistry, 141(2), (2013), 655-661.
There are 49 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Article
Authors

İbrahim Teğin 0000-0002-5661-7195

Selma Akdeniz 0009-0007-6865-8203

İhsan Alacabey 0000-0002-3080-2296

Kadir Erol 0000-0001-9158-6091

Orhan Acar 0000-0002-0969-2627

Project Number 2015-SİÜFEB-34
Publication Date December 25, 2023
Published in Issue Year 2023

Cite

APA Teğin, İ., Akdeniz, S., Alacabey, İ., Erol, K., et al. (2023). Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin. MANAS Journal of Engineering, 11(2), 177-189. https://doi.org/10.51354/mjen.1260477
AMA Teğin İ, Akdeniz S, Alacabey İ, Erol K, Acar O. Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin. MJEN. December 2023;11(2):177-189. doi:10.51354/mjen.1260477
Chicago Teğin, İbrahim, Selma Akdeniz, İhsan Alacabey, Kadir Erol, and Orhan Acar. “Preconcentration and Determination of Cu(II) and Cd(II) Ions from Wastewaters by Using Hazelnut Shell Biosorbent Immobilized on Amberlite XAD-4 Resin”. MANAS Journal of Engineering 11, no. 2 (December 2023): 177-89. https://doi.org/10.51354/mjen.1260477.
EndNote Teğin İ, Akdeniz S, Alacabey İ, Erol K, Acar O (December 1, 2023) Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin. MANAS Journal of Engineering 11 2 177–189.
IEEE İ. Teğin, S. Akdeniz, İ. Alacabey, K. Erol, and O. Acar, “Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin”, MJEN, vol. 11, no. 2, pp. 177–189, 2023, doi: 10.51354/mjen.1260477.
ISNAD Teğin, İbrahim et al. “Preconcentration and Determination of Cu(II) and Cd(II) Ions from Wastewaters by Using Hazelnut Shell Biosorbent Immobilized on Amberlite XAD-4 Resin”. MANAS Journal of Engineering 11/2 (December 2023), 177-189. https://doi.org/10.51354/mjen.1260477.
JAMA Teğin İ, Akdeniz S, Alacabey İ, Erol K, Acar O. Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin. MJEN. 2023;11:177–189.
MLA Teğin, İbrahim et al. “Preconcentration and Determination of Cu(II) and Cd(II) Ions from Wastewaters by Using Hazelnut Shell Biosorbent Immobilized on Amberlite XAD-4 Resin”. MANAS Journal of Engineering, vol. 11, no. 2, 2023, pp. 177-89, doi:10.51354/mjen.1260477.
Vancouver Teğin İ, Akdeniz S, Alacabey İ, Erol K, Acar O. Preconcentration and determination of Cu(II) and Cd(II) ions from wastewaters by using hazelnut shell biosorbent immobilized on Amberlite XAD-4 resin. MJEN. 2023;11(2):177-89.

Manas Journal of Engineering 

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