Fe–Mn/MCM-41: Preparation, Characterization, and Catalytic Activity for Methyl Orange in the Process of Heterogeneous Fenton Reaction

Xubin Zhang; Jianxin Dong; Zhencheng Hao; Wangfeng Cai; Fumin Wang

doi:10.1007/s12209-018-0122-1

Transactions of Tianjin University ›› 2018, Vol. 24 ›› Issue (4) : 361 -369. DOI: 10.1007/s12209-018-0122-1

Research Article

Fe–Mn/MCM-41: Preparation, Characterization, and Catalytic Activity for Methyl Orange in the Process of Heterogeneous Fenton Reaction

Author information +

History +

PDF

Abstract

Active Fe- and Mn-loaded MCM-41 (Fe–Mn/MCM-41), which was synthesized via a hydrothermal reaction followed by impregnation, is used in the heterogeneous Fenton reaction to degrade methyl orange (MO) in aqueous solution. The synthesized samples were characterized by X-ray diffraction, scanning electron microscopy, transmission electron microscopy, N₂ adsorption–desorption isotherm analysis, Fourier transform infrared spectroscopy, and X-ray photoelectron spectroscopy. Compared with Fe/MCM-41 and Mn/MCM-41, Fe–Mn/MCM-41 showed higher activity for MO degradation and mineralization. Effects of various operating parameters, such as pH, Mn content, and H₂O₂ dosage, on the degradation process were subsequently investigated. Results of experiments on the effect of radical scavengers revealed that the degradation of MO could be attributed to oxidation by HO·. The synergy of Fe and Mn species in the Fenton oxidation process was also explained.

Keywords

Heterogeneous Fenton / Fe–Mn/MCM-41 nanocomposite / Higher activity / Synergy

Cite this article

Download citation ▾

Xubin Zhang, Jianxin Dong, Zhencheng Hao, Wangfeng Cai, Fumin Wang. Fe–Mn/MCM-41: Preparation, Characterization, and Catalytic Activity for Methyl Orange in the Process of Heterogeneous Fenton Reaction. Transactions of Tianjin University, 2018, 24(4): 361-369 DOI:10.1007/s12209-018-0122-1

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Fernandez J, Maruthamuthu P, Kiwi J. Photobleaching and mineralization of Orange II by oxone and metal-ions involving Fenton-like chemistry under visible light. J Photochem Photobiol A, 2004, 161(2–3): 185-192.

[2]	Hoffmann MR, Martin ST, Choi W, et al. Environmental applications of semiconductor photocatalysis. Chem Rev, 1995, 95: 69-96.

[3]	Fu HB, Pan CS, Yao WQ, et al. Visible-light-induced degradation of rhodamine B by nanosized Bi₂WO₆. J Phys Chem B, 2005, 109(47): 22432-22439.

[4]	Nguyen TD, Phan NH, Do MH, et al. Magnetic Fe₂MO₄ (M: Fe, Mn) activated carbons: fabrication, characterization and heterogeneous Fenton oxidation of methyl orange. J Hazard Mater, 2011, 185(2–3): 653-661.

[5]	Li J, Ma WH, Huang YP, et al. Oxidative degradation of organic pollutants utilizing molecular oxygen and visible light over a supported catalyst of Fe (bpy)₃ ²⁺ in water. Appl Catal B, 2004, 48(1): 17-24.

[6]	Quici N, Morgada ME, Piperata G, et al. Oxalic acid destruction at high concentrations by combined heterogeneous photocatalysis and photo-Fenton processes. Catal Today, 2005, 101(3–4): 253-260.

[7]	Hammouda SB, Adhoum N, Monser L. Synthesis of magnetic alginate beads based on Fe₃O₄ nanoparticles for the removal of 3-methylindole from aqueous solution using Fenton process. J Hazard Mater, 2015, 294: 128-136.

[8]	Gao LZ, Zhuang J, Nie L, et al. Intrinsic peroxidase-like activity of ferromagnetic nanoparticles. Nat Nanotechnol, 2007, 2(9): 577-583.

[9]	Xu LJ, Wang JL. Magnetic nanoscaled Fe₃O₄/CeO₂ composite as an efficient Fenton-like heterogeneous catalyst for degradation of 4-chlorophenol. Environ Sci Technol, 2012, 46(18): 10145-10153.

[10]	Muthuvel I, Swaminathan M. Photoassisted Fenton mineralisation of acid violet 7 by heterogeneous Fe(III)-Al₂O₃ catalyst. Catal Commun, 2007, 8(7): 981-986.

[11]	Iurascu B, Siminiceanu I, Vione D, et al. Phenol degradation in water through a heterogeneous photo-Fenton process catalyzed by Fe-treated laponite. Water Res, 2009, 43(5): 1313-1322.

[12]	Chen QQ, Wu PX, Li YY, et al. Heterogeneous photo-Fenton photodegradation of reactive brilliant orange X-GN over iron-pillared montmorillonite under visible irradiation. J Hazard Mater, 2009, 168(2–3): 901-908.

[13]	Duarte F, Maldonado-Hódar FJ, Pérez-Cadenas AF, et al. Fenton-like degradation of azo-dye Orange II catalyzed by transition metals on carbon aerogels. Appl Catal B, 2009, 85(3–4): 139-147.

[14]	Ramirez JH, Maldonado-Hódar FJ, Pérez-Cadenas AF, et al. Azo-dye Orange II degradation by heterogeneous Fenton-like reaction using carbon-Fe catalysts. Appl Catal B, 2007, 75(3–4): 312-323.

[15]	Gonzalez-Olmos R, Roland U, Toufar H, et al. Fe-zeolites as catalysts for chemical oxidation of MTBE in water with H₂O₂. Appl Catal B, 2009, 89(3): 356-364.

[16]	Gonzalez-Olmos R, Martin MJ, Georgi A, et al. Fe-zeolites as heterogeneous catalysts in solar Fenton-like reactions at neutral pH. Appl Catal B, 2012, 125(3): 51-58.

[17]	Oliveira P, Machado A, Ramos AM, et al. MCM-41 anchored manganese salen complexes as catalysts for limonene oxidation. Microporous Mesoporous Mater, 2009, 120(3): 432-440.

[18]	Singh UG, Williams RT, Hallam KR, et al. Exploring the distribution of copper–Schiff base complex covalently anchored onto the surface of mesoporous MCM-41 silica. J Solid State Chem, 2005, 178(11): 3405-3413.

[19]	Chen ZW, Jiao Z, Pan DY, et al. Recent advances in manganese oxide nanocrystals: fabrication, characterization, and microstructure. Chem Rev, 2012, 112(7): 3833-3855.

[20]	Chen C, Ding GJ, Zhang D, et al. Microstructure evolution and advanced performance of Mn₃O₄ nanomorphologies. Nanoscale, 2012, 4(8): 2590-2596.

[21]	Einaga H, Yamamoto S, Maeda N, et al. Structural analysis of manganese oxides supported on SiO₂, for benzene oxidation with ozone. Catal Today, 2015, 242(2): 287-293.

[22]	Tang QH, Hu SQ, Chen YT, et al. Highly dispersed manganese oxide catalysts grafted on SBA-15: synthesis, characterization and catalytic application in trans-stilbene epoxidation. Microporous Mesoporous Mater, 2010, 132(3): 501-509.

[23]	Li JF, Yan NQ, Qu Z, et al. Catalytic oxidation of elemental mercury over the modified catalyst Mn/α-Al₂O₃ at lower temperatures. Environ Sci Technol, 2017, 44(1): 426-431.

[24]	Zhao J, Yang JJ, Ma J. Mn (II)-enhanced oxidation of benzoic acid by Fe(III)/H₂O₂ system. Chem Eng J, 2014, 239(3): 171-177.

[25]	Li YF, Sun JH, Sun SP. Mn²⁺-mediated homogeneous Fenton-like reaction of Fe(III)-NTA complex for efficient degradation of organic contaminants under neutral conditions. J Hazard Mater, 2016, 313: 193-200.

[26]	Huang RT, Liu YY, Chen ZW, et al. Fe-species-loaded mesoporous MnO₂ superstructural requirements for enhanced catalysis. ACS Appl Mater Interfaces, 2015, 7(7): 1-39.

[27]	Cai Q, Cui FZ, Chen XH, et al. Nanosphere of ordered silica MCM-41 hydrothermally synthesized with low surfactant concentration. Chem Lett, 2009, 29(9): 1044-1045.

[28]	Yonezawa T, Toshima N, Wakai C, et al. Structure of monoalkyl-monocationic surfactants on the microscopic three-dimensional platinum surface in water. Colloids Surf A, 2000, 169(1): 35-45.

[29]	Jiang YQ, Lin KF, Zhang YN, et al. Fe-MCM-41 nanoparticles as versatile catalysts for phenol hydroxylation and for Friedel–Crafts alkylation. Appl Catal A, 2012, 445–446: 172-179.

[30]	Huang RH, Lan BY, Chen ZY, et al. Catalytic ozonation of p-chlorobenzoic acid over MCM-41 and Fe loaded MCM-41. Chem Eng J, 2012, 180(3): 19-24.

[31]	Gaydhankar TR, Samuel V, Joshi PN. Hydrothermal synthesis of MCM-41 using differently manufactured amorphous dioxosilicon sources. Mater Lett, 2006, 60(7): 957-961.

[32]	Shen SH, Guo LJ. Hydrothermal synthesis, characterization, and photocatalytic performances of Cr incorporated, and Cr and Ti co-incorporated MCM-41 as visible light photocatalysts for water splitting. Catal Today, 2007, 129(3–4): 414-420.

[33]	Tsoncheva T, Rosenholm J, Linden M, et al. Critical evaluation of the state of iron oxide nanoparticles on different mesoporous silicas prepared by an impregnation method. Microporous Mesoporous Mater, 2008, 112(1): 327-337.

[34]	Rath D, Parida KM. Copper and nickel modified MCM-41 An efficient catalyst for hydrodehalogenation of chlorobenzene at room temperature. Ind Eng Chem Res, 2011, 50(5): 2839-2849.

[35]	Cuello NI, Elías VR, Torres CER, et al. Development of iron modified MCM-41 as promising nano-composites with specific magnetic behavior. Microporous Mesoporous Mater, 2015, 203: 106-115.

[36]	Han BQ, Zhang F, Feng ZP, et al. A designed Mn₂O₃/MCM-41 nanoporous composite for methylene blue and rhodamine B removal with high efficiency. Ceram Int, 2014, 40(6): 8093-8101.

[37]	Sheydaei M, Aber S, Khataee A. Degradation of amoxicillin in aqueous solution using nanolepidocrocite chips/H₂O₂/UV: optimization and kinetics studies. J Ind Eng Chem, 2014, 20(4): 1772-1778.

[38]	Guo J, Al-Dahhan M. Catalytic wet oxidation of phenol by hydrogen peroxide over pillared clay catalyst. Ind Eng Chem Res, 2003, 42(12): 2450-2460.

[39]	Cheng G, Lin J, Lu J, et al. Advanced treatment of pesticide-containing wastewater using Fenton reagent enhanced by microwave electrodeless ultraviolet. Biomed Res Int, 2015, 1–3: 205903.

[40]	Xia M, Long MC, Yang YD, et al. A highly active bimetallic oxides catalyst supported on Al-containing MCM-41 for Fenton oxidation of phenol solution. Appl Catal B, 2011, 110: 118-125.

[41]	Dutta K, Mukhopadhyay S, Bhattacharjee S, et al. Chemical oxidation of methylene blue using a Fenton-like reaction. J Hazard Mater, 2001, 84(1): 57-71.

[42]	Watts RJ, Bottenberg BC, Hess TF, et al. Role of reductants in the enhanced desorption and transformation of chloroaliphatic compounds by modified Fenton’s reactions. Environ Sci Technol, 1999, 33: 3432-3437.

[43]	Watts RJ, Sarasa J, Loge FJ, et al. Oxidative and reductive pathways in manganese-catalyzed Fenton’s reactions. J Environ Eng, 2005, 131(1): 158-164.

[44]	Do SH, Batchelor B, Lee HK, et al. Hydrogen peroxide decomposition on manganese oxide (pyrolusite): kinetics, intermediates, and mechanism. Chemosphere, 2009, 75(1): 8-12.