Research Article
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Year 2023, Volume: 6 Issue: 2, 35 - 44, 01.10.2023
https://doi.org/10.58692/jotcsb.1240859

Abstract

References

  • Ahmed, S. A., Gaber, A. A. A., & Rahim, A. M. A. (2017). Application of silica fume as a new SP-extractor for trace determination of Zn (II) and Cd (II) in pharmaceutical and environmental samples by square-wave anodic stripping voltammetry. Applied Water Science, 7(2), 677-688.
  • Aşçı, Y. (2013). Decolorization of Direct Orange 26 by heterogeneous Fenton oxidation. Desalination and Water Treatment, 51(40-42), 7612-7620.
  • Aziz, K., Aziz, F., Mamouni, R., Aziz, L., Anfar, Z., Azrrar, A., . . . Laknifli, A. (2022). High thiabendazole fungicide uptake using Cellana tramoserica shells modified by copper: Characterization, adsorption mechanism, and optimization using CCD-RSM approach. Environmental Science and Pollution Research, 29(57), 86020-86035.
  • Bazgir, A., Khorshidi, A., Kamani, H., Ashrafi, S. D., & Naghipour, D. (2019). Modeling of azo dyes adsorption on magnetic NiFe 2 O 4/RGO nanocomposite using response surface methodology. Journal of Environmental Health Science and Engineering, 17, 931-947.
  • Chinonye, O.A., Oluchukwu, A.C., & Elijah, O.C. (2018), Statistical analysis for orange G adsorption using kola nut shell activated carbon. Journal of the Chinese Advanced Materials Society, 6(4), 605-619.
  • Dargahi, A., Samarghandi, M. R., Shabanloo, A., Mahmoudi, M. M., & Nasab, H. Z. (2021). Statistical modeling of phenolic compounds adsorption onto low-cost adsorbent prepared from aloe vera leaves wastes using CCD-RSM optimization: effect of parameters, isotherm, and kinetic studies. Biomass Conversion and Biorefinery, 1-15.
  • Dbik, A., El Messaoudi, N., Bentahar, S., El Khomri, M., Lacherai, A., & Faska, N. (2022). Optimization of Methylene Blue Adsorption on Agricultural Solid Waste Using Box–Behnken Design (BBD) Combined with Response Surface Methodology (RSM) Modeling. Biointerface Research in Applied Chemistry, 12(4), 4567-4583.
  • Genc, A., & Oguz, A. (2010). Sorption of acid dyes from aqueous solution by using non-ground ash and slag. Desalination, 264(1-2), 78-83.
  • Geyikçi, F., Kılıç, E., Çoruh, S., & Elevli, S. (2012). Modelling of lead adsorption from industrial sludge leachate on red mud by using RSM and ANN. Chemical Engineering Journal, 183, 53-59.
  • Ghaedi, M., Hajati, S., Zaree, M., Shajaripour, Y., Asfaram, A., & Purkait, M. (2015). Removal of methyl orange by multiwall carbon nanotube accelerated by ultrasound devise: Optimized experimental design. Advanced Powder Technology, 26(4), 1087-1093.
  • Kalkan, E., Nadaroglu, H., & Celebi, N. (2014). Use of Silica Fume as Low-Cost Absorbent Material for Nickel Removal from Aqueous Solutions. Asian Journal of Chemistry, 26(18).
  • Kannaujiya, M. C., Gupta, G. K., Mandal, T., & Mondal, M. K. (2022). Adsorption of Acid Yellow 2GL dye from simulated water using brinjal waste. Biomass Conversion and Biorefinery, 1-14.
  • Li, X., Han, C., Zhu, W., Ma, W., Luo, Y., Zhou, Y., . . . Wei, K. (2014). Cr (VI) removal from aqueous by adsorption on amine-functionalized mesoporous silica prepared from silica fume. Journal of Chemistry, ID 765856, 1-10.
  • Montgomery, D. C. (2017). Design and analysis of experiments: John wiley & sons.
  • Nadaroglu, H., & Kalkan, E. (2014). Removal of copper from aqueous solution using activated silica fume with/without apocarbonic anhydrase.
  • Safa, Y., & Bhatti, H. N. (2011). Kinetic and thermodynamic modeling for the removal of Direct Red-31 and Direct Orange-26 dyes from aqueous solutions by rice husk. Desalination, 272(1-3), 313-322.
  • Sohrabi, M. R., Moghri, M., Masoumi, H. R. F., Amiri, S., & Moosavi, N. (2016). Optimization of Reactive Blue 21 removal by Nanoscale Zero-Valent Iron using response surface methodology. Arabian journal of chemistry, 9(4), 518-525.
  • Tariq, W., Arslan, C., Naqvi, S. A., Abdullah, M., Nasir, A., Gillani, S. H., . . . Yamin, M. (2022). Photocatalytic Removal of Azo Dyes Using a CNT Doped ZnO/Fe<sub>2</sub>O<sub>3</sub> Catalyst. Polish Journal of Environmental Studies, 31(5), 4279-4289. doi:10.15244/pjoes/131805
  • Tomczak, E., & Tosik, P. (2014). Sorption equilibrium of azo dyes Direct Orange 26 and Reactive Blue 81 onto a cheap plant sorbent. Ecological Chemistry and Engineering.
  • Wang, Y., & Chu, W. (2011). Adsorption and removal of a xanthene dye from aqueous solution using two solid wastes as adsorbents. Industrial & engineering chemistry research, 50(14), 8734-8741.
  • Yan, L.-g., Qin, L.-l., Yu, H.-q., Li, S., Shan, R.-r., & Du, B. (2015). Adsorption of acid dyes from aqueous solution by CTMAB modified bentonite: kinetic and isotherm modeling. Journal of Molecular Liquids, 211, 1074-1081.
  • Zhang, D., Ma, Y., Feng, H., Wang, Y., & Hao, Y. (2012). Preparation and characterization of the carbon–Microsilica composite sorbent. Advanced Powder Technology, 23(2), 215-219.
  • Zhu, X., Zhang, Z., & Yan, G. (2016). Methylene blue adsorption by novel magnetic chitosan nanoadsorbent. Journal of Water and Environment Technology, 14(2), 96-105.

RSM Optimization of Direct Orange 26 Adsorption on Low-Cost Silica Fume Adsorbent

Year 2023, Volume: 6 Issue: 2, 35 - 44, 01.10.2023
https://doi.org/10.58692/jotcsb.1240859

Abstract

Today, dye pollutants enter resources of water through various industries. Due to the stability and carcinogenicity of dye pollutants, it is necessary to treat colored wastewater before entering the aqueous cycle. One of the important methods for wastewater treatment is adsorption. In this study, the effect of industrial waste of silica fume adsorbent on azo dye Direct Orange 26 (DO26) was investigated. Design of experiment was carried out with CCD method by using Design Expert software version 7 to model and investigate the effects of parameters pH, concentration, amount of adsorbent, and time. The model proposed by the software is a second-order model. According to the findings, important and effective parameters for the quadratic model of experimental design were obtained from ANOVA (analysis of variance). The optimum conditions for the maximum removal of DO26 (95.26%) were obtained to be at pH 2.01, contact time of 55.15 minutes, adsorbent amount of 0.2 g, and initial concentration of 44 ppm. The experimental kinetic data were analyzed through the conventional kinetic models, and the results demonstrate that the sorption kinetics can be accurately described by the pseudo-second order model. Also, based on FESEM image, silica fume has a spherical and porous structure, therefore, silica fume can remove dye pollutants from water as a cheap adsorbent.

References

  • Ahmed, S. A., Gaber, A. A. A., & Rahim, A. M. A. (2017). Application of silica fume as a new SP-extractor for trace determination of Zn (II) and Cd (II) in pharmaceutical and environmental samples by square-wave anodic stripping voltammetry. Applied Water Science, 7(2), 677-688.
  • Aşçı, Y. (2013). Decolorization of Direct Orange 26 by heterogeneous Fenton oxidation. Desalination and Water Treatment, 51(40-42), 7612-7620.
  • Aziz, K., Aziz, F., Mamouni, R., Aziz, L., Anfar, Z., Azrrar, A., . . . Laknifli, A. (2022). High thiabendazole fungicide uptake using Cellana tramoserica shells modified by copper: Characterization, adsorption mechanism, and optimization using CCD-RSM approach. Environmental Science and Pollution Research, 29(57), 86020-86035.
  • Bazgir, A., Khorshidi, A., Kamani, H., Ashrafi, S. D., & Naghipour, D. (2019). Modeling of azo dyes adsorption on magnetic NiFe 2 O 4/RGO nanocomposite using response surface methodology. Journal of Environmental Health Science and Engineering, 17, 931-947.
  • Chinonye, O.A., Oluchukwu, A.C., & Elijah, O.C. (2018), Statistical analysis for orange G adsorption using kola nut shell activated carbon. Journal of the Chinese Advanced Materials Society, 6(4), 605-619.
  • Dargahi, A., Samarghandi, M. R., Shabanloo, A., Mahmoudi, M. M., & Nasab, H. Z. (2021). Statistical modeling of phenolic compounds adsorption onto low-cost adsorbent prepared from aloe vera leaves wastes using CCD-RSM optimization: effect of parameters, isotherm, and kinetic studies. Biomass Conversion and Biorefinery, 1-15.
  • Dbik, A., El Messaoudi, N., Bentahar, S., El Khomri, M., Lacherai, A., & Faska, N. (2022). Optimization of Methylene Blue Adsorption on Agricultural Solid Waste Using Box–Behnken Design (BBD) Combined with Response Surface Methodology (RSM) Modeling. Biointerface Research in Applied Chemistry, 12(4), 4567-4583.
  • Genc, A., & Oguz, A. (2010). Sorption of acid dyes from aqueous solution by using non-ground ash and slag. Desalination, 264(1-2), 78-83.
  • Geyikçi, F., Kılıç, E., Çoruh, S., & Elevli, S. (2012). Modelling of lead adsorption from industrial sludge leachate on red mud by using RSM and ANN. Chemical Engineering Journal, 183, 53-59.
  • Ghaedi, M., Hajati, S., Zaree, M., Shajaripour, Y., Asfaram, A., & Purkait, M. (2015). Removal of methyl orange by multiwall carbon nanotube accelerated by ultrasound devise: Optimized experimental design. Advanced Powder Technology, 26(4), 1087-1093.
  • Kalkan, E., Nadaroglu, H., & Celebi, N. (2014). Use of Silica Fume as Low-Cost Absorbent Material for Nickel Removal from Aqueous Solutions. Asian Journal of Chemistry, 26(18).
  • Kannaujiya, M. C., Gupta, G. K., Mandal, T., & Mondal, M. K. (2022). Adsorption of Acid Yellow 2GL dye from simulated water using brinjal waste. Biomass Conversion and Biorefinery, 1-14.
  • Li, X., Han, C., Zhu, W., Ma, W., Luo, Y., Zhou, Y., . . . Wei, K. (2014). Cr (VI) removal from aqueous by adsorption on amine-functionalized mesoporous silica prepared from silica fume. Journal of Chemistry, ID 765856, 1-10.
  • Montgomery, D. C. (2017). Design and analysis of experiments: John wiley & sons.
  • Nadaroglu, H., & Kalkan, E. (2014). Removal of copper from aqueous solution using activated silica fume with/without apocarbonic anhydrase.
  • Safa, Y., & Bhatti, H. N. (2011). Kinetic and thermodynamic modeling for the removal of Direct Red-31 and Direct Orange-26 dyes from aqueous solutions by rice husk. Desalination, 272(1-3), 313-322.
  • Sohrabi, M. R., Moghri, M., Masoumi, H. R. F., Amiri, S., & Moosavi, N. (2016). Optimization of Reactive Blue 21 removal by Nanoscale Zero-Valent Iron using response surface methodology. Arabian journal of chemistry, 9(4), 518-525.
  • Tariq, W., Arslan, C., Naqvi, S. A., Abdullah, M., Nasir, A., Gillani, S. H., . . . Yamin, M. (2022). Photocatalytic Removal of Azo Dyes Using a CNT Doped ZnO/Fe<sub>2</sub>O<sub>3</sub> Catalyst. Polish Journal of Environmental Studies, 31(5), 4279-4289. doi:10.15244/pjoes/131805
  • Tomczak, E., & Tosik, P. (2014). Sorption equilibrium of azo dyes Direct Orange 26 and Reactive Blue 81 onto a cheap plant sorbent. Ecological Chemistry and Engineering.
  • Wang, Y., & Chu, W. (2011). Adsorption and removal of a xanthene dye from aqueous solution using two solid wastes as adsorbents. Industrial & engineering chemistry research, 50(14), 8734-8741.
  • Yan, L.-g., Qin, L.-l., Yu, H.-q., Li, S., Shan, R.-r., & Du, B. (2015). Adsorption of acid dyes from aqueous solution by CTMAB modified bentonite: kinetic and isotherm modeling. Journal of Molecular Liquids, 211, 1074-1081.
  • Zhang, D., Ma, Y., Feng, H., Wang, Y., & Hao, Y. (2012). Preparation and characterization of the carbon–Microsilica composite sorbent. Advanced Powder Technology, 23(2), 215-219.
  • Zhu, X., Zhang, Z., & Yan, G. (2016). Methylene blue adsorption by novel magnetic chitosan nanoadsorbent. Journal of Water and Environment Technology, 14(2), 96-105.
There are 23 citations in total.

Details

Primary Language English
Subjects Chemical Engineering, Wastewater Treatment Processes, Materials Science and Technologies
Journal Section Full-length articles
Authors

Shohre Mortazavi 0000-0002-2845-6902

Ebrahim Najafi Kani This is me 0000-0001-9613-8060

Publication Date October 1, 2023
Submission Date January 23, 2023
Acceptance Date July 5, 2023
Published in Issue Year 2023 Volume: 6 Issue: 2

Cite

APA Mortazavi, S., & Najafi Kani, E. (2023). RSM Optimization of Direct Orange 26 Adsorption on Low-Cost Silica Fume Adsorbent. Journal of the Turkish Chemical Society Section B: Chemical Engineering, 6(2), 35-44. https://doi.org/10.58692/jotcsb.1240859

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This piece of scholarly information is licensed under Creative Commons Atıf-GayriTicari-AynıLisanslaPaylaş 4.0 Uluslararası Lisansı.

J. Turk. Chem. Soc., Sect. B: Chem. Eng. (JOTCSB)