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Year 2024, Volume: 17 Issue: 2, 308 - 326, 31.08.2024
https://doi.org/10.18185/erzifbed.1384410

Abstract

References

  • [1] Tirtom,VN., Goulding, Ş., Henden, E. (2008) Application of a wool column for flow injection online preconcentration of inorganic mercury(II) and methyl mercury species prior to atomic fluorescence measurement. Talanta, 76, 1212-1217.
  • [2] Bhattacharyya, A., Dutta, S., De, P., Ray, P., Basu, S. (2010) Removal of mercury (II) from aqueous solution using papain immobilized on alginate bead: Optimization of immobilization condition and modeling of removal study. Bioresource Technology, 101(24), 9421-9428.
  • [3] Natale, F., Di, Lancia, A., Molino, A., Di Natale, M., Karatza, D., Musmarra, D. (2006) Capture of mercury ions by natural and industrial materials. Journal of Hazardous Materials B, 132: 220-225.
  • [4] Ma, Rao., M, K, Reddy, DHK., Venkateswarlu, P., Seshaiah, K. (2009) Removal of mercury from aqueous solutions using activated carbon prepared from agricultural by-product/waste. Journal of Environmental Management, 90: 634-643.
  • [5] Yardim, MF., Budinova, T., Ekinci, E., Petrov, N., Razvigorova, M., Minkova, V. (2003) Removal of mercury(II) from aqueous solution by activated carbon obtained from furfural. Chemosphere, 52(5): 835-841.
  • [6] Kumar, D., Tomar, V. (2014) New generation material for the removal of arsenic from water. Advanced Materials For Agriculture, Food, And Environmental Safety, 3: 61-85.
  • [7] Imran, A., Tabrez AK., Asım, M. (2011) Removal of arsenic from water by electrocoagulation and electrodialysis techniques. Separation & Purification Reviews; 40: 25-42.
  • [8] Wang, Y., Yu, J., Wang, Z., Liu, Y., Zhao, Y. (2021) A review on arsenic removal from coal combustion: Advances, challenges and opportunities. Chemical Engineering Journal, 414: 128785.
  • [9] Kaçar, E., (2022) Relationship of concentrations of some heavy metals with fish size in muscle tissue of carassius gibelio (Bloch, 1782) from the Tigris River (Turkey), Erzincan University Journal of Science and Technology, 15(2): 475-484.
  • [10] SALTAN, G. M., (2023) Synthesis and characterization of terpolymer adsorbents using photopolymerization: ınvestigation of heavy metal adsorption capacity, Erzincan University Journal of Science and Technology,16(2): 528-547
  • [11] Kannan, N., Malar, SJS. (2005) Removal mercury(II) ions by adsorption onto dates nut and commercial activated carbons: a comparative study. Indian Journal of Chemical Technology, 12: 522-527.
  • [12] Hassan, SSM., Awwad, NS, Aboterik, AHA. (2008). Removal of mercury(II) from wastewater using camel bone charcoal. Journal of Hazardous Materials, 154(1–3): 992-997.
  • [13] Akbal, FÖ., Akdemir, N., Onar, AN. (2000) FT-IR spectroscopic detection of pesticide after sorption onto modified pumice. Talanta, 53:131-135.
  • [14] Akbal, F. (2005) Adsorption of basic dyes from aqueous solution onto pumice powder. Journal of Colloid Interface Science, 286: 455–458.
  • [15] Asgari, G., Roshani, B., Ghanizadehc, G. (2012) The investigation of kinetic and isotherm of fluoride adsorption onto functionalize pumice stone. Journal of Hazardous Material, 217–218: 123-132.
  • [16] Ersoy, B., Sariisik, A., Dikmen, Sariisik, G. (2010) Characterization of acidic pumice and determination of its electrokinetic properties in water. Powder Technology, 197:129–135.
  • [17] Erdem, F., Ergun, Mübeccel., (2020) Application of response surface methodology for removal of remazol yellow (rr) by ımmobilised s. cerevisiae on pumice stone. Iranian Journal of Chemistry and Chemical Engineering, 39(3): 175-187.
  • [18] Güler, Ülkü, Aslı., Sarioglu, Meltem., (2014) Removal of tetracycline from wastewater using pumice stone: equilibrium, kinetic and thermodynamic studies. Journal of Environmental Health Science & Engineering, 12:79
  • [19] Ilhan, S., Iscen, C., Caner, FN., Kiran, I. (2008) Biosorption potential of dried penicillium restrictum for reactive orange 122: isotherm, kinetic and thermodynamic studies. Journal of Chemical Technology & Biotechnology, 83(4): 569-575.
  • [20] Kargi, F., Cikla, S. (2006) Zinc(II) ion recovery by biosorption onto powdered waste sludge (PWS): effects of operating conditions. Journal of Chemical Technology & Biotechnology, 81(10):1661-1668.
  • [21] Arcibar-Orozco, J.A., Josue, D., Rios-Hurtado, J.C., Rangel- Mendez, J.R. (2014) Influence of iron content, surface area and charge distribution in the arsenic removal by activated carbons, Chemical Engineering Journal, 249: 201–209.
  • [22] Zhang, F.S., Nriagu, JO., Itoh, H. (2005) Mercury removal from water using activated carbons derived from organic sewage sludge. Water Research, 39: 389-395.
  • [23] Bayramoglu, G., Tuzun, I., Celik, G., Yilmaz, M., Arica, Y., (2006) Biosorption of mercury(II), cadmium(II) and lead(II) ions fromaqueous systembymicroalgae Chlamydomonas reinhardtii immobilized in alginate beads. International Journal of Mineral Processing, 81: 35-43.
  • [24] Inbaraj, BS., Sulochana, N. (2006) Mercury adsorption on a carbon sorbent derived from fruit shell of Terminalia catappa. Journal of Hazardous Materials; 133: 283-290.
  • [25] Zeroual, Y., Moutaouakkil, A., Dzairi, FZ., Talbi, M., Park, UC., Lee, K., Blaghen, M. (2003) Biosorption of mercury from aqueous solution by Ulva lactuca biomass. Bioresource Technology, 90(3): 349-351.
  • [26] Wan, M., W, Kan, CC., Rogel, BD., Dalida, MLP. (2010) Adsorption of copper (II) and lead (II) ions from aqueous solution on chitosan-coated sand. Carbohydrate Polymers, 80: 891-899.
  • [27] Chatterjee, S., Chatterjee, S., Chatterjee, BP., Guha, AK. (2007) Adsorptive removal of Congo red, a carcinogenic textile dye by chitosan hydrobeads: binding mechanism, equilibrium and kinetics. Colloids and Surfaces A; Physicochemical and Engineering Aspects, 299(1):146-152.
  • [28] Ng, JCY., Cheung, WH., McKay G. (2003) Equilibrium studies for the sorption of lead from effluents using chitosan. Chemosphere, 52:1021-1030.
  • [28] Freundlich, HMF. 1906. Uber die adsorption in lasungen, Zeitschrift für Physikalische Chemie: 57, 385-470.
  • [30] Zhang, YK., Yan LG., Xu WY., Guo XY., Cui LM., Gao L., Wei Q., Du, B. (2014) Adsorption of Pb(II) and Hg(II) from aqueous solution using magnetic CoFe2O4-reduced graphene oxide. Journal of Molecular Liquids, 191; 177–182.
  • [31] Tadayon, F., Saber-Tehrani, M., Motahar, S. (2013) Selective removal mercury (II) from aqueous solution using silica aerogel modified with 4- amino-5-methyl-1,2,4-triazole-3(4H)-thion. Korean Journal of Chemical Engineering, 30; 642–648.
  • [32] Yu, Y., Addai-Mensah, J., Losic, D. (2012) Functionalized diatom silica microparticles for removal of mercury ions. Science and Technology of Advanced Materials, 13: 015008
  • [33] Daifullah, AAM., Awwad, NS., Al-Azhar. (2003) Bulletin of Science; in: Proceeding of 5th Int. Sci. Conf: 25–27 March, 57.
  • [34] Bricka, RM., Hill D.O. in: P.L. Cote, T.M. (1989) Gilliam (Eds.), ASTM STP 1033, American Society for Testing and Materials, 257, Philadelphia.
  • [35] Jat Baloch MY., Su C., Talpur, SA., Iqbal, J., Bajwa, K. (2023) Arsenic Removal from groundwater using iron pyrite: influence factors and removal mechanism, Journal of Earth Science XX, 1-11.
  • [36] Habuda-Stanić, M., Nujić, M. (2015) Arsenic removal by nanoparticles: a review, Environ Science and Pollution Research International, 22: 8094–8123.
  • [37] Gupta, A., Yunus, M., Sankararamakrishnan, N. 2012. Zerovalent iron encapsulated chitosan nanospheres—a novel adsorbent for the removal of total inorganic arsenic from aqueous systems. Chemosphere, 86:150–155.
  • [38] Nguyen, Thanh, D., Singh, M., Ulbrich, P., Strnadova, N., Štěpánek, F. (2011) Perlite incorporating γ-Fe2O3 and α-MnO2 nanomaterials: preparation and evaluation of a new adsorbent for As(V) removal. Separation & Purification Technology, 82: 93–10.
  • [39] Martinson, CA., Reddy, KJ. (2009) Adsorption of arsenic(III) and arsenic(V) by cupric oxide nanoparticles. Journal of Colloid Interface Science, 336, 406–411.

Use of Activated and Modified Pumice Stone for Removal of Mercury (II) and Arsenic (III) Ions From Aqueous Solution

Year 2024, Volume: 17 Issue: 2, 308 - 326, 31.08.2024
https://doi.org/10.18185/erzifbed.1384410

Abstract

Removal of Hg (II) and As (III) ions from aqueous solutions using activated and modified pumice stone were investigated. The pH, temperature, initial metal ion concentration which are very important for removal studies, were investigated by batch method. The experiments demonstrated that the equilibrium adsorption data fit the Freundlich isotherm model well for Hg (II) and As (III) ions. The negative value of ΔH° = -199.92 kJ mol-1 and -78,15 kJ mol-1 for mercury (II) and arsenic (III) ions indicates that the adsorption process is exothermic. ΔS° were calculated as -267.85 J K-1 mol-1 for As (III) ions and the positive value of ΔS° = 0.69 kJ K-1 mol-1 for Hg (II) ions. The negative value of ΔG°=-405.14 kJ mol-1 for Hg (II) ions and -1.67 kJ mol-1 for As (III) ions indicates that adsorption is voluntary. EDTA has been found to be a good desorbent in desorption studies to recover arsenic and Hg ions. The experiments show that pumice stone can be used for Hg (II) and As (III) removal in aqueous solution.

References

  • [1] Tirtom,VN., Goulding, Ş., Henden, E. (2008) Application of a wool column for flow injection online preconcentration of inorganic mercury(II) and methyl mercury species prior to atomic fluorescence measurement. Talanta, 76, 1212-1217.
  • [2] Bhattacharyya, A., Dutta, S., De, P., Ray, P., Basu, S. (2010) Removal of mercury (II) from aqueous solution using papain immobilized on alginate bead: Optimization of immobilization condition and modeling of removal study. Bioresource Technology, 101(24), 9421-9428.
  • [3] Natale, F., Di, Lancia, A., Molino, A., Di Natale, M., Karatza, D., Musmarra, D. (2006) Capture of mercury ions by natural and industrial materials. Journal of Hazardous Materials B, 132: 220-225.
  • [4] Ma, Rao., M, K, Reddy, DHK., Venkateswarlu, P., Seshaiah, K. (2009) Removal of mercury from aqueous solutions using activated carbon prepared from agricultural by-product/waste. Journal of Environmental Management, 90: 634-643.
  • [5] Yardim, MF., Budinova, T., Ekinci, E., Petrov, N., Razvigorova, M., Minkova, V. (2003) Removal of mercury(II) from aqueous solution by activated carbon obtained from furfural. Chemosphere, 52(5): 835-841.
  • [6] Kumar, D., Tomar, V. (2014) New generation material for the removal of arsenic from water. Advanced Materials For Agriculture, Food, And Environmental Safety, 3: 61-85.
  • [7] Imran, A., Tabrez AK., Asım, M. (2011) Removal of arsenic from water by electrocoagulation and electrodialysis techniques. Separation & Purification Reviews; 40: 25-42.
  • [8] Wang, Y., Yu, J., Wang, Z., Liu, Y., Zhao, Y. (2021) A review on arsenic removal from coal combustion: Advances, challenges and opportunities. Chemical Engineering Journal, 414: 128785.
  • [9] Kaçar, E., (2022) Relationship of concentrations of some heavy metals with fish size in muscle tissue of carassius gibelio (Bloch, 1782) from the Tigris River (Turkey), Erzincan University Journal of Science and Technology, 15(2): 475-484.
  • [10] SALTAN, G. M., (2023) Synthesis and characterization of terpolymer adsorbents using photopolymerization: ınvestigation of heavy metal adsorption capacity, Erzincan University Journal of Science and Technology,16(2): 528-547
  • [11] Kannan, N., Malar, SJS. (2005) Removal mercury(II) ions by adsorption onto dates nut and commercial activated carbons: a comparative study. Indian Journal of Chemical Technology, 12: 522-527.
  • [12] Hassan, SSM., Awwad, NS, Aboterik, AHA. (2008). Removal of mercury(II) from wastewater using camel bone charcoal. Journal of Hazardous Materials, 154(1–3): 992-997.
  • [13] Akbal, FÖ., Akdemir, N., Onar, AN. (2000) FT-IR spectroscopic detection of pesticide after sorption onto modified pumice. Talanta, 53:131-135.
  • [14] Akbal, F. (2005) Adsorption of basic dyes from aqueous solution onto pumice powder. Journal of Colloid Interface Science, 286: 455–458.
  • [15] Asgari, G., Roshani, B., Ghanizadehc, G. (2012) The investigation of kinetic and isotherm of fluoride adsorption onto functionalize pumice stone. Journal of Hazardous Material, 217–218: 123-132.
  • [16] Ersoy, B., Sariisik, A., Dikmen, Sariisik, G. (2010) Characterization of acidic pumice and determination of its electrokinetic properties in water. Powder Technology, 197:129–135.
  • [17] Erdem, F., Ergun, Mübeccel., (2020) Application of response surface methodology for removal of remazol yellow (rr) by ımmobilised s. cerevisiae on pumice stone. Iranian Journal of Chemistry and Chemical Engineering, 39(3): 175-187.
  • [18] Güler, Ülkü, Aslı., Sarioglu, Meltem., (2014) Removal of tetracycline from wastewater using pumice stone: equilibrium, kinetic and thermodynamic studies. Journal of Environmental Health Science & Engineering, 12:79
  • [19] Ilhan, S., Iscen, C., Caner, FN., Kiran, I. (2008) Biosorption potential of dried penicillium restrictum for reactive orange 122: isotherm, kinetic and thermodynamic studies. Journal of Chemical Technology & Biotechnology, 83(4): 569-575.
  • [20] Kargi, F., Cikla, S. (2006) Zinc(II) ion recovery by biosorption onto powdered waste sludge (PWS): effects of operating conditions. Journal of Chemical Technology & Biotechnology, 81(10):1661-1668.
  • [21] Arcibar-Orozco, J.A., Josue, D., Rios-Hurtado, J.C., Rangel- Mendez, J.R. (2014) Influence of iron content, surface area and charge distribution in the arsenic removal by activated carbons, Chemical Engineering Journal, 249: 201–209.
  • [22] Zhang, F.S., Nriagu, JO., Itoh, H. (2005) Mercury removal from water using activated carbons derived from organic sewage sludge. Water Research, 39: 389-395.
  • [23] Bayramoglu, G., Tuzun, I., Celik, G., Yilmaz, M., Arica, Y., (2006) Biosorption of mercury(II), cadmium(II) and lead(II) ions fromaqueous systembymicroalgae Chlamydomonas reinhardtii immobilized in alginate beads. International Journal of Mineral Processing, 81: 35-43.
  • [24] Inbaraj, BS., Sulochana, N. (2006) Mercury adsorption on a carbon sorbent derived from fruit shell of Terminalia catappa. Journal of Hazardous Materials; 133: 283-290.
  • [25] Zeroual, Y., Moutaouakkil, A., Dzairi, FZ., Talbi, M., Park, UC., Lee, K., Blaghen, M. (2003) Biosorption of mercury from aqueous solution by Ulva lactuca biomass. Bioresource Technology, 90(3): 349-351.
  • [26] Wan, M., W, Kan, CC., Rogel, BD., Dalida, MLP. (2010) Adsorption of copper (II) and lead (II) ions from aqueous solution on chitosan-coated sand. Carbohydrate Polymers, 80: 891-899.
  • [27] Chatterjee, S., Chatterjee, S., Chatterjee, BP., Guha, AK. (2007) Adsorptive removal of Congo red, a carcinogenic textile dye by chitosan hydrobeads: binding mechanism, equilibrium and kinetics. Colloids and Surfaces A; Physicochemical and Engineering Aspects, 299(1):146-152.
  • [28] Ng, JCY., Cheung, WH., McKay G. (2003) Equilibrium studies for the sorption of lead from effluents using chitosan. Chemosphere, 52:1021-1030.
  • [28] Freundlich, HMF. 1906. Uber die adsorption in lasungen, Zeitschrift für Physikalische Chemie: 57, 385-470.
  • [30] Zhang, YK., Yan LG., Xu WY., Guo XY., Cui LM., Gao L., Wei Q., Du, B. (2014) Adsorption of Pb(II) and Hg(II) from aqueous solution using magnetic CoFe2O4-reduced graphene oxide. Journal of Molecular Liquids, 191; 177–182.
  • [31] Tadayon, F., Saber-Tehrani, M., Motahar, S. (2013) Selective removal mercury (II) from aqueous solution using silica aerogel modified with 4- amino-5-methyl-1,2,4-triazole-3(4H)-thion. Korean Journal of Chemical Engineering, 30; 642–648.
  • [32] Yu, Y., Addai-Mensah, J., Losic, D. (2012) Functionalized diatom silica microparticles for removal of mercury ions. Science and Technology of Advanced Materials, 13: 015008
  • [33] Daifullah, AAM., Awwad, NS., Al-Azhar. (2003) Bulletin of Science; in: Proceeding of 5th Int. Sci. Conf: 25–27 March, 57.
  • [34] Bricka, RM., Hill D.O. in: P.L. Cote, T.M. (1989) Gilliam (Eds.), ASTM STP 1033, American Society for Testing and Materials, 257, Philadelphia.
  • [35] Jat Baloch MY., Su C., Talpur, SA., Iqbal, J., Bajwa, K. (2023) Arsenic Removal from groundwater using iron pyrite: influence factors and removal mechanism, Journal of Earth Science XX, 1-11.
  • [36] Habuda-Stanić, M., Nujić, M. (2015) Arsenic removal by nanoparticles: a review, Environ Science and Pollution Research International, 22: 8094–8123.
  • [37] Gupta, A., Yunus, M., Sankararamakrishnan, N. 2012. Zerovalent iron encapsulated chitosan nanospheres—a novel adsorbent for the removal of total inorganic arsenic from aqueous systems. Chemosphere, 86:150–155.
  • [38] Nguyen, Thanh, D., Singh, M., Ulbrich, P., Strnadova, N., Štěpánek, F. (2011) Perlite incorporating γ-Fe2O3 and α-MnO2 nanomaterials: preparation and evaluation of a new adsorbent for As(V) removal. Separation & Purification Technology, 82: 93–10.
  • [39] Martinson, CA., Reddy, KJ. (2009) Adsorption of arsenic(III) and arsenic(V) by cupric oxide nanoparticles. Journal of Colloid Interface Science, 336, 406–411.
There are 39 citations in total.

Details

Primary Language English
Subjects Separation Science
Journal Section Makaleler
Authors

Vedia Nüket Tirtom 0000-0002-2490-2741

Publication Date August 31, 2024
Submission Date November 1, 2023
Acceptance Date May 28, 2024
Published in Issue Year 2024 Volume: 17 Issue: 2

Cite

APA Tirtom, V. N. (2024). Use of Activated and Modified Pumice Stone for Removal of Mercury (II) and Arsenic (III) Ions From Aqueous Solution. Erzincan University Journal of Science and Technology, 17(2), 308-326. https://doi.org/10.18185/erzifbed.1384410