Year 2024,
Volume: 25 Issue: 3, 390 - 406, 30.09.2024
İlknur Demıral
,
Canan Şamdan
,
Fatma Betül Kus
References
- [1] Schneider K, Hafner C, Jäger I. Mutagenicity of textile dye products. J Appl Toxicol. 2004; 24 (2), 83-91.
- [2] Deep Red Cas#: 3564-22-5. ChemicalBook. https://m.chemicalbook.com/Product ChemicalProperties CB8356989_EN.htm. Accessed May 29, 2024.
- [3] Sulistina DR, Martini S. The Effect of Rhodamine B on the Cerebellum and Brainstem Tissue of Rattus Norvegicus. J Public Health Res. 2020; 9 (2).
- [4] Environmental Law. 1983. https://www.mevzuat.gov.tr/MevzuatMetin/1.5.2872.pdf. Accessed June 22, 2023.
- [5] Water Pollution Control Regulation.; 2004:25687. https://www.mevzuat.gov.tr/mevzuat? MevzuatNo=7221&MevzuatTur=7&MevzuatTertip=5. Accessed June 22, 2023.
- [6] Inamuddin. Applications of Adsorption and Ion Exchange Chromatography in Waste Water Treatment. Materials Research Forum LLC, 2017.
- [7] Wong CW, Barford JP, Chen G, McKay G. Kinetics and equilibrium studies for the removal of cadmium ions by ion exchange resin. J Environ Chem Eng. 2014; 2 (1), 698-707.
- [8] Zamora-Ledezma C, Negrete-Bolagay D, Figueroa F, Zamora-Ledezma E, Ni M, Alexis F, et al. Heavy metal water pollution: A fresh look about hazards, novel and conventional remediation methods. Environ Technol Innov. 2021; 22, 101504.
- [9] Secondes MFN, Naddeo V, Belgiorno V, Ballesteros F. Removal of emerging contaminants by simultaneous application of membrane ultrafiltration, activated carbon adsorption, and ultrasound irradiation. J Hazard Mater. 2014; 264, 342-349.
- [10] Abdel-Fatah MA. Nanofiltration systems and applications in wastewater treatment: Review article. Ain Shams Eng J. 2018;9 (4), 3077-3092.
- [11] Teh CY, Budiman PM, Shak KPY, Wu TY. Recent Advancement of Coagulation–Flocculation and Its Application in Wastewater Treatment. Ind Eng Chem Res. 2016; 55 (16), 4363-4389.
- [12] Savci S, Donmez S, Mazmanci MA. Performance And Mechanısms Of Malachıte Green Dye Adsorptıon Usıng Industrıal Solıd Waste As Adsorbent. Environ Eng Manag J. 2023; 22 (1), 97-104.
- [13] Simsek R, Ciftci BN, Uysal Y. An Experımental Study On The Effıcıency Of Chromıum (VI) Removal Wıth Starch-Magnetıte Nanocomposıte (Starch@Mnps). Anadolu Univ J Sci Technol- Appl Sci Eng. 2020; 21 (2), 322-334..
- [14] Dikmen S, Ersoy B, Dikmen Z. Adsorptıon Behavıour Of Ionıc And Non-Ionıc Surfactants Onto Talc A Naturally Hydrophobıc Mıneral-A Comparatıve Study. Eskişehir Tech Univ J Sci Technol - Appl Sci Eng. 2020; 21 (1), 139-152.
- [15] Savci S, Uysal MM. Adsorption of Methylene Blue and Methyl Orange By Using Waste Ash. Süleyman Demirel Üniversitesi Fen Bilim Enstitüsü Derg. 2017; 21 (3), 831.
- [16] Neolaka YAB, Riwu AAP, Aigbe UO, Ukhurebor KE, Onyancha RB, Darmokoesoemo H, et al. Potential of activated carbon from various sources as a low-cost adsorbent to remove heavy metals and synthetic dyes. Results Chem. 2023; 5, 100711.
- [17] Başar B, Şayan E. Optımızatıon Of Selectıve Cu2+ Adsorptıon Wıthın The Multı-Ion System By Usıng Actıvated Carbon Prepared By Ultrasound. Anadolu Univ J Sci Technol- Appl Sci Eng. 2018; 19 (4), 893-906.
- [18] Manasa P, Sambasivam S, Ran F. Recent progress on biomass waste derived activated carbon electrode materials for supercapacitors applications—A review. J Energy Storage. 2022; 54, 105290.
- [19] Yağmur HK, Kaya İ. Synthesis and characterization of magnetic ZnCl2-activated carbon produced from coconut shell for the adsorption of methylene blue. J Mol Struct. 2021; 1232, 130071.
- [20] Syed-Hassan SSA, Zaini MSM. Optimization of the preparation of activated carbon from palm kernel shell for methane adsorption using Taguchi orthogonal array design. Korean J Chem Eng. 2016; 33 (8), 2502-2512.
- [21] Boudechiche N, Fares M, Ouyahia S, Yazid H, Trari M, Sadaoui Z. Comparative study on removal of two basic dyes in aqueous medium by adsorption using activated carbon from Ziziphus lotus stones. Microchem J. 2019; 146, 1010-1018.
- [22] Kundu A, Sen Gupta B, Hashim MA, Redzwan G. Taguchi optimization approach for production of activated carbon from phosphoric acid impregnated palm kernel shell by microwave heating. J Clean Prod. 2015; 105, 420-427.
- [23] Meti̇n N, Savci S. Adsorption of Malachite Green by An Agricultural Waste: Rice Husk. Türk Tarım Ve Doğa Bilim Derg. 2021; 8 (1), 23-29.
- [24] Mosoarca G, Vancea C, Popa S, Gheju M, Boran S. Syringa vulgaris leaves powder a novel low-cost adsorbent for methylene blue removal: isotherms, kinetics, thermodynamic and optimization by Taguchi method. Sci Rep. 2020; 10 (1), 17676.
- [25] Srenscek-Nazzal J, Kamińska W, Michalkiewicz B, Koren ZC. Production, characterization and methane storage potential of KOH-activated carbon from sugarcane molasses. Ind Crops Prod. 2013; 47, 153-159.
- [26] Luo Y, Li D, Chen Y, Sun X, Cao Q, Liu X. The performance of phosphoric acid in the preparation of activated carbon-containing phosphorus species from rice husk residue. J Mater Sci. 2019; 54 (6), 5008-5021.
- [27] Aravindhan R, Raghava Rao J, Unni Nair B. Preparation and characterization of activated carbon from marine macro-algal biomass. J Hazard Mater. 2009; 162 (2-3), 688-694.
- [28] Eshghi A, kheirmand M. Graphene/Ni–Fe layered double hydroxide nano composites as advanced electrode materials for glucose electro oxidation. Int J Hydrog Energy. 2017; 42 (22), 15064-15072.
- [29] Das MP. Removal of Methylene Blue by Adsorption Using Fish Scale Chitin. Nat Environ Pollut Technol. 2018; 17 (3), 7.
- [30] Wong KT, Wong VL, Lim SS. Bio-sorptive Removal of Methyl Orange by Micro-Grooved Chitosan (GCS) Beads: Optimization of Process Variables Using Taguchi L9 Orthogonal Array. J Polym Environ. 2021; 29 (1), 271-290.
- [31] Mahmoud ME. Water treatment of hexavalent chromium by gelatin-impregnated-yeast (Gel–Yst) biosorbent. J Environ Manage. 2015; 147, 264-270.
- [32] Chen L, Zhu Y, Cui Y, Dai R, Shan Z, Chen H. Fabrication of starch-based high-performance adsorptive hydrogels using a novel effective pretreatment and adsorption for cationic methylene blue dye: Behavior and mechanism. Chem Eng J. 2021; 405, 126953.
- [33] Malini K, Selvakumar D, Kumar NS. Activated carbon from biomass: Preparation, factors improving basicity and surface properties for enhanced CO2 capture capacity – A review. J CO2 Util. 2023; 67, 102318.
- [34] Zhang Y, Song X, Xu Y, Shen H, Kong X, Xu H. Utilization of wheat bran for producing activated carbon with high specific surface area via NaOH activation using industrial furnace. J Clean Prod. 2019; 210, 366-375.
- [35] Alomar T, Qiblawey H, Almomani F, Al-Raoush RI, Han DS, Ahmad NM. Recent advances on humic acid removal from wastewater using adsorption process. J Water Process Eng. 2023; 53, 103679.
- [36] Derici C. Production of Activated Carbon from Kidney Bean Shells and Its Use in Dyestuff Removal. Master Thesis. Eskişehir Osmangazi University Institute of Science and Technology, 2021.
- [37] Khaled A, El Nemr A, El-Sikaily A, Abdelwahab O. Treatment of artificial textile dye effluent containing Direct Yellow 12 by orange peel carbon. Desalination. 2009; 238 (1), 210-232.
- [38] Torres-Perez J, Gerente C, Andres Y. Conversion of agricultural residues into activated carbons for water purification: Application to arsenate removal. J Environ Sci Health Part A. 2012; 47 (8), 1173-1185.
- [39] Hydari S, Sharififard H, Nabavinia M, Parvizi MR. A comparative investigation on removal performances of commercial activated carbon, chitosan biosorbent and chitosan/activated carbon composite for cadmium. Chem Eng J. 2012; 193-194.
- [40] Garg V. Basic dye (methylene blue) removal from simulated wastewater by adsorption using Indian Rosewood sawdust: a timber industry waste. Dyes Pigments. 2004; 63 (3), 243-250.
- [41] Naghizadeh A, Momeni F, Kamani H. Study of Ultrasonic Regeneration and Adsorption of Humic Acid on Activated Carbon. Health Scope. 2018; 7 (2).
- [42] Danish M, Ahmad T, Majeed S, Ahmad M, Ziyang L, Pin Z, et al. Use of banana trunk waste as activated carbon in scavenging methylene blue dye: Kinetic, thermodynamic, and isotherm studies. Bioresour Technol Rep. 2018; 3, 127-137.
- [43] Gerçel Ö, Özcan A, Özcan AS, Gerçel HF. Preparation of activated carbon from a renewable bio-plant of Euphorbia rigida by H2SO4 activation and its adsorption behavior in aqueous solutions. Appl Surf Sci. 2007; 253 (11), 4843-4852.
- [44] Mei D, Liu L, Yan B. Adsorption of uranium (VI) by metal-organic frameworks and covalent-organic frameworks from water. Coord Chem Rev. 2023; 475, 214917.
- [45] Benjelloun M, Miyah Y, Akdemir Evrendilek G, Zerrouq F, Lairini S. Recent Advances in Adsorption Kinetic Models: Their Application to Dye Types. Arab J Chem. 2021; 14 (4), 103031.
- [46] Chen S, Qin C, Wang T, Chen F, Li X, Hou H, et al. Study on the adsorption of dyestuffs with different properties by sludge-rice husk biochar: Adsorption capacity, isotherm, kinetic, thermodynamics and mechanism. J Mol Liq. 2019; 285, 62-74.
DETERMINATION OF DEEP RED REMOVAL POTENTIAL OF ACTIVATED CARBON PRODUCED FROM WHEAT BRAN
Year 2024,
Volume: 25 Issue: 3, 390 - 406, 30.09.2024
İlknur Demıral
,
Canan Şamdan
,
Fatma Betül Kus
Abstract
In this study, the production of activated carbon from wheat bran was carried out through the chemical activation method. ZnCl2 was used as the chemical agent in the chemical activation. The impregnation ratio was determined as 2:1, and the activation temperature was set to 500 °C. The obtained activated carbon was utilized for the removal of the Deep red dye substance from aqueous solutions. The adsorption studies resulted in the highest adsorption capacity under conditions of pH 2.17, a duration of 24 h and a temperature of 45 °C, providing a removal of 95.238 mg/g. The adsorption studies were evaluated by examining adsorption isotherms, adsorption kinetics, and adsorption thermodynamics. It was determined that this adsorption study is in accordance with the pseudo-second-order kinetic model and Langmuir isotherm. According to adsorption thermodynamics, adsorption is endothermic and occurs physically. These results indicate that activated carbon produced from wheat bran can be effectively used to remove the Deep red dye substance from wastewater.
References
- [1] Schneider K, Hafner C, Jäger I. Mutagenicity of textile dye products. J Appl Toxicol. 2004; 24 (2), 83-91.
- [2] Deep Red Cas#: 3564-22-5. ChemicalBook. https://m.chemicalbook.com/Product ChemicalProperties CB8356989_EN.htm. Accessed May 29, 2024.
- [3] Sulistina DR, Martini S. The Effect of Rhodamine B on the Cerebellum and Brainstem Tissue of Rattus Norvegicus. J Public Health Res. 2020; 9 (2).
- [4] Environmental Law. 1983. https://www.mevzuat.gov.tr/MevzuatMetin/1.5.2872.pdf. Accessed June 22, 2023.
- [5] Water Pollution Control Regulation.; 2004:25687. https://www.mevzuat.gov.tr/mevzuat? MevzuatNo=7221&MevzuatTur=7&MevzuatTertip=5. Accessed June 22, 2023.
- [6] Inamuddin. Applications of Adsorption and Ion Exchange Chromatography in Waste Water Treatment. Materials Research Forum LLC, 2017.
- [7] Wong CW, Barford JP, Chen G, McKay G. Kinetics and equilibrium studies for the removal of cadmium ions by ion exchange resin. J Environ Chem Eng. 2014; 2 (1), 698-707.
- [8] Zamora-Ledezma C, Negrete-Bolagay D, Figueroa F, Zamora-Ledezma E, Ni M, Alexis F, et al. Heavy metal water pollution: A fresh look about hazards, novel and conventional remediation methods. Environ Technol Innov. 2021; 22, 101504.
- [9] Secondes MFN, Naddeo V, Belgiorno V, Ballesteros F. Removal of emerging contaminants by simultaneous application of membrane ultrafiltration, activated carbon adsorption, and ultrasound irradiation. J Hazard Mater. 2014; 264, 342-349.
- [10] Abdel-Fatah MA. Nanofiltration systems and applications in wastewater treatment: Review article. Ain Shams Eng J. 2018;9 (4), 3077-3092.
- [11] Teh CY, Budiman PM, Shak KPY, Wu TY. Recent Advancement of Coagulation–Flocculation and Its Application in Wastewater Treatment. Ind Eng Chem Res. 2016; 55 (16), 4363-4389.
- [12] Savci S, Donmez S, Mazmanci MA. Performance And Mechanısms Of Malachıte Green Dye Adsorptıon Usıng Industrıal Solıd Waste As Adsorbent. Environ Eng Manag J. 2023; 22 (1), 97-104.
- [13] Simsek R, Ciftci BN, Uysal Y. An Experımental Study On The Effıcıency Of Chromıum (VI) Removal Wıth Starch-Magnetıte Nanocomposıte (Starch@Mnps). Anadolu Univ J Sci Technol- Appl Sci Eng. 2020; 21 (2), 322-334..
- [14] Dikmen S, Ersoy B, Dikmen Z. Adsorptıon Behavıour Of Ionıc And Non-Ionıc Surfactants Onto Talc A Naturally Hydrophobıc Mıneral-A Comparatıve Study. Eskişehir Tech Univ J Sci Technol - Appl Sci Eng. 2020; 21 (1), 139-152.
- [15] Savci S, Uysal MM. Adsorption of Methylene Blue and Methyl Orange By Using Waste Ash. Süleyman Demirel Üniversitesi Fen Bilim Enstitüsü Derg. 2017; 21 (3), 831.
- [16] Neolaka YAB, Riwu AAP, Aigbe UO, Ukhurebor KE, Onyancha RB, Darmokoesoemo H, et al. Potential of activated carbon from various sources as a low-cost adsorbent to remove heavy metals and synthetic dyes. Results Chem. 2023; 5, 100711.
- [17] Başar B, Şayan E. Optımızatıon Of Selectıve Cu2+ Adsorptıon Wıthın The Multı-Ion System By Usıng Actıvated Carbon Prepared By Ultrasound. Anadolu Univ J Sci Technol- Appl Sci Eng. 2018; 19 (4), 893-906.
- [18] Manasa P, Sambasivam S, Ran F. Recent progress on biomass waste derived activated carbon electrode materials for supercapacitors applications—A review. J Energy Storage. 2022; 54, 105290.
- [19] Yağmur HK, Kaya İ. Synthesis and characterization of magnetic ZnCl2-activated carbon produced from coconut shell for the adsorption of methylene blue. J Mol Struct. 2021; 1232, 130071.
- [20] Syed-Hassan SSA, Zaini MSM. Optimization of the preparation of activated carbon from palm kernel shell for methane adsorption using Taguchi orthogonal array design. Korean J Chem Eng. 2016; 33 (8), 2502-2512.
- [21] Boudechiche N, Fares M, Ouyahia S, Yazid H, Trari M, Sadaoui Z. Comparative study on removal of two basic dyes in aqueous medium by adsorption using activated carbon from Ziziphus lotus stones. Microchem J. 2019; 146, 1010-1018.
- [22] Kundu A, Sen Gupta B, Hashim MA, Redzwan G. Taguchi optimization approach for production of activated carbon from phosphoric acid impregnated palm kernel shell by microwave heating. J Clean Prod. 2015; 105, 420-427.
- [23] Meti̇n N, Savci S. Adsorption of Malachite Green by An Agricultural Waste: Rice Husk. Türk Tarım Ve Doğa Bilim Derg. 2021; 8 (1), 23-29.
- [24] Mosoarca G, Vancea C, Popa S, Gheju M, Boran S. Syringa vulgaris leaves powder a novel low-cost adsorbent for methylene blue removal: isotherms, kinetics, thermodynamic and optimization by Taguchi method. Sci Rep. 2020; 10 (1), 17676.
- [25] Srenscek-Nazzal J, Kamińska W, Michalkiewicz B, Koren ZC. Production, characterization and methane storage potential of KOH-activated carbon from sugarcane molasses. Ind Crops Prod. 2013; 47, 153-159.
- [26] Luo Y, Li D, Chen Y, Sun X, Cao Q, Liu X. The performance of phosphoric acid in the preparation of activated carbon-containing phosphorus species from rice husk residue. J Mater Sci. 2019; 54 (6), 5008-5021.
- [27] Aravindhan R, Raghava Rao J, Unni Nair B. Preparation and characterization of activated carbon from marine macro-algal biomass. J Hazard Mater. 2009; 162 (2-3), 688-694.
- [28] Eshghi A, kheirmand M. Graphene/Ni–Fe layered double hydroxide nano composites as advanced electrode materials for glucose electro oxidation. Int J Hydrog Energy. 2017; 42 (22), 15064-15072.
- [29] Das MP. Removal of Methylene Blue by Adsorption Using Fish Scale Chitin. Nat Environ Pollut Technol. 2018; 17 (3), 7.
- [30] Wong KT, Wong VL, Lim SS. Bio-sorptive Removal of Methyl Orange by Micro-Grooved Chitosan (GCS) Beads: Optimization of Process Variables Using Taguchi L9 Orthogonal Array. J Polym Environ. 2021; 29 (1), 271-290.
- [31] Mahmoud ME. Water treatment of hexavalent chromium by gelatin-impregnated-yeast (Gel–Yst) biosorbent. J Environ Manage. 2015; 147, 264-270.
- [32] Chen L, Zhu Y, Cui Y, Dai R, Shan Z, Chen H. Fabrication of starch-based high-performance adsorptive hydrogels using a novel effective pretreatment and adsorption for cationic methylene blue dye: Behavior and mechanism. Chem Eng J. 2021; 405, 126953.
- [33] Malini K, Selvakumar D, Kumar NS. Activated carbon from biomass: Preparation, factors improving basicity and surface properties for enhanced CO2 capture capacity – A review. J CO2 Util. 2023; 67, 102318.
- [34] Zhang Y, Song X, Xu Y, Shen H, Kong X, Xu H. Utilization of wheat bran for producing activated carbon with high specific surface area via NaOH activation using industrial furnace. J Clean Prod. 2019; 210, 366-375.
- [35] Alomar T, Qiblawey H, Almomani F, Al-Raoush RI, Han DS, Ahmad NM. Recent advances on humic acid removal from wastewater using adsorption process. J Water Process Eng. 2023; 53, 103679.
- [36] Derici C. Production of Activated Carbon from Kidney Bean Shells and Its Use in Dyestuff Removal. Master Thesis. Eskişehir Osmangazi University Institute of Science and Technology, 2021.
- [37] Khaled A, El Nemr A, El-Sikaily A, Abdelwahab O. Treatment of artificial textile dye effluent containing Direct Yellow 12 by orange peel carbon. Desalination. 2009; 238 (1), 210-232.
- [38] Torres-Perez J, Gerente C, Andres Y. Conversion of agricultural residues into activated carbons for water purification: Application to arsenate removal. J Environ Sci Health Part A. 2012; 47 (8), 1173-1185.
- [39] Hydari S, Sharififard H, Nabavinia M, Parvizi MR. A comparative investigation on removal performances of commercial activated carbon, chitosan biosorbent and chitosan/activated carbon composite for cadmium. Chem Eng J. 2012; 193-194.
- [40] Garg V. Basic dye (methylene blue) removal from simulated wastewater by adsorption using Indian Rosewood sawdust: a timber industry waste. Dyes Pigments. 2004; 63 (3), 243-250.
- [41] Naghizadeh A, Momeni F, Kamani H. Study of Ultrasonic Regeneration and Adsorption of Humic Acid on Activated Carbon. Health Scope. 2018; 7 (2).
- [42] Danish M, Ahmad T, Majeed S, Ahmad M, Ziyang L, Pin Z, et al. Use of banana trunk waste as activated carbon in scavenging methylene blue dye: Kinetic, thermodynamic, and isotherm studies. Bioresour Technol Rep. 2018; 3, 127-137.
- [43] Gerçel Ö, Özcan A, Özcan AS, Gerçel HF. Preparation of activated carbon from a renewable bio-plant of Euphorbia rigida by H2SO4 activation and its adsorption behavior in aqueous solutions. Appl Surf Sci. 2007; 253 (11), 4843-4852.
- [44] Mei D, Liu L, Yan B. Adsorption of uranium (VI) by metal-organic frameworks and covalent-organic frameworks from water. Coord Chem Rev. 2023; 475, 214917.
- [45] Benjelloun M, Miyah Y, Akdemir Evrendilek G, Zerrouq F, Lairini S. Recent Advances in Adsorption Kinetic Models: Their Application to Dye Types. Arab J Chem. 2021; 14 (4), 103031.
- [46] Chen S, Qin C, Wang T, Chen F, Li X, Hou H, et al. Study on the adsorption of dyestuffs with different properties by sludge-rice husk biochar: Adsorption capacity, isotherm, kinetic, thermodynamics and mechanism. J Mol Liq. 2019; 285, 62-74.