PDF(2229 KB)
Carbon nanotubes-incorporated MIL-88B-Fe as highly efficient Fenton-like catalyst for degradation of organic pollutants
Hang Zhang, Shuo Chen, Haiguang Zhang, Xinfei Fan, Cong Gao, Hongtao Yu, Xie Quan
PDF(2229 KB)
PDF(2229 KB)
Carbon nanotubes-incorporated MIL-88B-Fe as highly efficient Fenton-like catalyst for degradation of organic pollutants
CNTs were incorporated into MIL-88B-Fe to get a new Fenton-like catalyst (C@M).
Fe(II) was introduced in C@M to get a fast initiation of Fenton-like reaction.
Fe(II) content in C@M was related with oxygen-containing functional groups on CNTs.
C@M shows efficient catalytic degradation of pollutants over a wide pH range.
Iron-based metal organic frameworks have been verified to be efficient heterogeneous Fenton catalysts due to their open pore channels and highly uniform distribution of metallic centers. In these catalysts, however, the iron element is mainly in the form of Fe(III), which results in a process required to reduce Fe(III) to Fe(II) to initiate Fenton reaction. To address this problem, carbon nanotubes (CNTs) with electron-rich oxygen-functional groups on the surface were incorporated into the metal organic frameworks (MIL-88B-Fe) to improve Fe(II) content for an enhanced Fenton-like performance. The prepared CNT@MIL-88B-Fe (C@M) showed much stronger catalytic ability toward H2O2 than MIL-88B-Fe. The pseudo-first-order kinetic constant for phenol degradation by C@M (0.32 min–1) was about 7 times that of MIL-88B-Fe, and even higher than or comparable to the values of reported heterogeneous Fenton-like catalysts. Moreover, the Fenton-like system could effectively degrade various kinds of refractory organic pollutants and exhibited excellent catalytic activity over a wide pH range (4–9). XPS analysis confirmed that Fe(II) content of the catalyst gradually increased with CNT loadings. Electron spin resonance analysis showed that the signal intensity (•OH) of C@M was much higher than MIL-88B-Fe, which was consistent with the degradation efficiency of pollutants. Furthermore, the Fe(II) content of the catalyst gradually increased along with the oxygen-functional group content of CNTs. The result demonstrated that oxygen-containing functional groups of CNTs have a significant impact on the enhanced catalytic performance of C@M. This study provides a new insight to enhance Fenton reaction by using nanocarbon materials.
Heterogeneous Fenton-like catalysts / MIL-88B-Fe / CNTs / Organic pollutants / Mechanism
| [1] |
Araya T, Jia M, Yang J, Zhao P, Cai K, Ma W H, Huang Y P (2017). Resin modified MIL-53 (Fe) MOF for improvement of photocatalytic performance. Applied Catalysis B: Environmental, 203: 768–777
|
| [2] |
Branca C,Frusteri F, Magazù V, Mangione A (2004). Characterization of carbon nanotubes by TEM and Infrared Spectroscopy. The Journal of Physical Chemistry B, 108(11): 3469–3473
|
| [3] |
Chen D Z, Chen S S, Jiang Y J, Xie S S, Quan H Y, Hua L, Luo X B, Guo L (2017). Heterogeneous Fenton-like catalysis of Fe-MOF derived magnetic carbon nanocomposites for degradation of 4-nitrophenol. RSC Advances, 7(77): 49024–49030
|
| [4] |
Duan H T, Liu Y, Yin X H, Bai J F, Qi J (2016). Degradation of nitrobenzene by Fenton-like reaction in a H2O2/schwertmannite system. Chemical Engineering Journal, 283: 873–879
|
| [5] |
Duarte F, Maldonado-Hódar F J, Pérez-Cadenas A F, Madeira L M (2009). Fenton-like degradation of azo-dye orange II catalyzed by transition metals on carbon aerogels. Applied Catalysis B: Environmental, 85(3): 139–147
|
| [6] |
Gao C, Chen S, Quan X, Yu H T, Zhang Y B (2017). Enhanced Fenton-like catalysis by iron-based metal organic frameworks for degradation of organic pollutants. Journal of Catalysis, 356: 125–132
|
| [7] |
Gonzalez-Olmos R, Holzer F, Kopinke F D, Georgi A (2011). Indications of the reactive species in a heterogeneous Fenton-like reaction using Fe-containing zeolites. Applied Catalysis A: General, 398(1): 44–53
|
| [8] |
Hou X, Huang X, Ai Z, Zhao J, Zhang L (2016). Ascorbic acid/Fe@Fe2O3: A highly efficient combined Fenton reagent to remove organic contaminants. Journal of Hazardous Materials, 310: 170–178
|
| [9] |
Ji Y, Huang L, Hu J, Streb C, Song Y F (2015). Polyoxometalate-functionalized nanocarbon materials for energy conversion, energy storage and sensor systems. Energy & Environmental Science, 8(3): 776–789
|
| [10] |
Jia Z, Duan X G, Qin P, Zhang W C,Wang W M, Yang C, Sun H Q, Wang S B, Zhang L C (2017a). Sordered atomic packing structure of metallic glass: Toward ultrafast hydroxyl radicals production rate and strong electron transfer ability in catalytic performance. Advanced Functional Materials, 27(38): 1–9
|
| [11] |
Jia Z, Wang J C, Liang S X, Zhang W C, Wang W M, Zhang L C(2017b). Activation of peroxymonosulfate by Fe78Si9B13 metallic glass: The influence of crystallization. Journal of Alloys and Compounds, 728: 525–533
|
| [12] |
Jin H, Tian X, Nie Y, Zhou Z, Yang C, Li Y, Lu L (2017). Oxygen vacancy promoted heterogeneous Fenton-like degradation of ofloxacin at pH 3.2–9.0 by Cu substituted magnetic Fe3O4@FeOOH nanocomposite. Environmental Science & Technology, 51(21): 12699–12706
|
| [13] |
Kim J, Kim S N, Jang H G,Seo G, Ahn W S (2013). CO2 cycloaddition of styrene oxide over MOF catalysts. Applied Catalysis A: General, 453: 175–180
|
| [14] |
Kim K, Zhu P, Li N, Ma X, Chen Y (2011). Characterization of oxygen containing functional groups on carbon materials with oxygen K-edge X-ray absorption near edge structure spectroscopy. Carbon, 49(5): 1745–1751
|
| [15] |
Laurier K G M, Vermoortele F, Ameloot R., DeVos D E, Hofkens J, Roeffaers M B J (2013). Iron(III)-based metal–organic frameworks as visible light photocatalysts. Journal of the American Chemical Society, 135(39): 14488–14491
|
| [16] |
Li Y H, Xu C, Wei B, Zhang X, Zheng M, Wu D, Ajayan P M (2002). Self-organized ribbons of aligned carbon nanotubes. Chemistry of Materials, 14(2): 483–485
|
| [17] |
Liang S X, Jia Z, Liu Y J, Zhang W C, Wang W M, Lu J, Zhang L C (2018a). Compelling rejuvenated catalytic performance in metallic glasses. Advanced Materials, 1802764: 1–11
|
| [18] |
Liang S X, Jia Z, Zhang W C, Li X F, Wang W M, Lin H C, Zhang L C (2018b). Ultrafast activation efficiency of three peroxides by Fe78SiB13 metallic glass under photo-enhanced catalytic oxidation: A comparative study. Applied Catalysis B: Environmental, 221: 108–118
|
| [19] |
Lu Y B, He S L, Wang D T, Luo S Y, Liu A P, Luo H P, Liu G L, Zhang R D (2018). A pulsed switching peroxi-coagulation process to control hydroxyl radical production and enhance 2,4-Dichlorphenoxyacetic acid degradation. Frontiers of Environmental Science & Engineering, 12(5): 9
|
| [20] |
Lv H, Zhao H, Cao T, Qian L, Wang Y, Zhao G (2015). Efficient degradation of high concentration azo-dye wastewater by heterogeneous Fenton process with iron-based metal-organic framework. Journal of Molecular Catalysis A: Chemical, 400: 81–89
|
| [21] |
Lyu L, Zhang L, Hu C, Yang M (2016). Enhanced Fenton-catalytic efficiency by highly accessible active sites on dandelion-like copper-aluminum-silica nanospheres for water purification. Journal of Materials Chemistry A, 4(22): 8610–8619
|
| [22] |
Ma M, Noei H, Mienert B, Niesel J, Bill E, Muhler M, Fisher R A, Wang Y M, Schatzschneider U, Metzler-Nolte N (2013). Iron metal–organic frameworks MIL-88B and NH2-MIL-88B for the loading and delivery of the gasotransmitter carbon monoxide. Chemistry – A European Journal, 19(21): 6785–6790
|
| [23] |
Mao J, Quan X, Wang J, Gao C, Chen S, Yu H T, Zhao Y B (2018). Enhanced heterogeneous Fenton-like activity by Cu-doped BiFeO3 perovskite for degradation of organic pollutants. Frontiers of Environmental Science & Engineering, 12(6): 10
|
| [24] |
Navalon S, Martin R, Alvaro M, Garcia H (2010). Gold on diamond nanoparticles as a highly efficient Fenton catalyst. Angewande Chemie International Edition, 49(45): 8403–8407
|
| [25] |
Ou X X, Yan J F, Zhang F J, Zhang C H (2018). Accelerated degradation of orange G over a wide pH range in the presence of FeVO4. Frontiers of Environmental Science & Engineering, 12(1): 7
|
| [26] |
Peng J, Xue J, Li J,Du Z, Wang Z, Gao S (2017). Catalytic effect of low concentration carboxylated multi-walled carbon nanotubes on the oxidation of disinfectants with Cl-substituted structure by a Fenton-like system. Chemical Engineering Journal, 321: 325–334
|
| [27] |
Qin Y, Zhang L, An T (2017). Hydrothermal carbon-mediated Fenton-like reaction mechanism in the degradation of alachlor: direct electron transfer from hydrothermal carbon to Fe(III). Applied Materials & Interfaces, 9: 17115–17124
|
| [28] |
Restivo J, Órfão J J M, Armenise S, Garcia-Bordejé E, Pereira M F R (2012). Catalytic ozonation of metolachlor under continuous operation using nanocarbon materials grown on a ceramic monolith. Journal of Hazardous Materials, 239– 240: 249–256
|
| [29] |
Shearer C J, Alexey C, Dominik E (2014). Application and future challenges of functional nanocarbon hybrids. Advanced Materials, 26(15): 2295–2318
|
| [30] |
Sun J H, Sun S P, Fan M H, Guo H Q, Qiao L P, Sun R X (2007). A kinetic study on the degradation of p-nitroaniline by Fenton oxidation process. Journal of Hazardous Materials, 148(1): 172–177
|
| [31] |
Sun M, Chu C, Geng F, Lu X, Qu J, Crittenden J, Elimelech M, Kim J H (2018). Reinventing Fenton chemistry: Iron oxychloride nanosheet for pH-insensitive H2O2 activation. Environmental Science & Technology Letters, 5(3): 186–191
|
| [32] |
Tang J, Wang J (2018). Metal organic framework with coordinatively unsaturated sites as efficient Fenton-like catalyst for enhanced degradation of sulfamethazine. Environmental Science & Technology, 52(9): 5367–5377
|
| [33] |
Tian S, Zhang J, Chen J, Kong L, Lu J, Ding F, Xiong Y (2013). Fe2(MoO4)3 as an effective photo-Fenton-like catalyst for the degradation of anionic and cationic dyes in a wide pH range. Industrial & Engineering Chemistry Research, 52(37): 13333–13341
|
| [34] |
Wang D W, Su D (2014). Heterogeneous nanocarbon materials for oxygen reduction reaction. Energy & Environmental Science, 7(2): 576–591
|
| [35] |
Wang J, Bai Z (2017). Fe-based catalysts for heterogeneous catalytic ozonation of emerging contaminants in water and wastewater. Chemical Engineering Journal, 312: 79–98
|
| [36] |
Wang X, Wang G, Chen S, Fan X, Quan X, Yu H (2017). Integration of membrane filtration and photoelectrocatalysis on g-C3N4/CNTs/Al2O3 membrane with visible-light response for enhanced water treatment. Journal of Membrane Science, 541: 153–161
|
| [37] |
Wang Y, Zhao H, Zhao G (2015). Iron-copper bimetallic nanoparticles embedded within ordered mesoporous carbon as effective and stable heterogeneous Fenton catalyst for the degradation of organic contaminants. Applied Catalysis B: Environmental, 164: 396–406
|
| [38] |
Wu Y Y, Yang C X, Yan X P (2014). Fabrication of metal-organic framework MIL-88B films on stainless steel fibers for solid-phase microextraction of polychlorinated biphenyls. Journal of Chromatography A, 1334: 1–8
|
| [39] |
Yang D Q,Rochette J F, Sacher E (2005). Functionalization of multiwalled carbon nanotubes by mild aqueous sonication. The Journal of Physical Chemistry B, 109(16): 7788–7794
|
| [40] |
Yang Z, Yu A, Shan C, Gao G, Pan B (2018). Enhanced Fe(III)-mediated Fenton oxidation of atrazine in the presence of functionalized multi-walled carbon nanotubes. Water Research, 137(15): 37–46
|
| [41] |
Yin D, Zhang L, Zhao X, Chen H, Zhai Q (2015). Iron-glutamate-silicotungstate ternary complex as highly active heterogeneous Fenton-like catalyst for 4-chlorophenol degradation. Chinese Journal of Catalysis, 36(12): 2203–2210
|
| [42] |
Yu L, Yang X, Ye Y, Wang D (2015). Efficient removal of atrazine in water with a Fe3O4/MWCNTs nanocomposite as a heterogeneous Fenton-like catalyst. RSC Advances, 5(57): 46059–46066
|
| [43] |
Zhang G,Gao Y, Zhang Y, Guo Y (2010). Fe2O3-pillared rectorite as an efficient and stable Fenton-Like heterogeneous catalyst for photodegradation of organic contaminants. Environmental Science & Technology, 44(16): 6384–6389
|
| [44] |
Zhang L, Nie Y, Hu C, Qu J (2012). Enhanced Fenton degradation of Rhodamine B over nanoscaled Cu-doped LaTiO3 perovskite. Applied Catalysis B: Environmental, 125(21): 418–424
|
| [45] |
Zhang X Y, Ding Y B, Tang H Q, Han X Y, Zhu L H,Wang N (2014). Degradation of bisphenol A by hydrogen peroxide activated with CuFeO2 microparticles as a heterogeneous Fenton-like catalyst: Efficiency, stability and mechanism. Chemical Engineering Journal, 236(15): 251–262
|
| [46] |
Zhou H, Shen Y F, Wang J Y, Chen X, O’Young C L, Suib S L (1998). Studies of decomposition of H2O2 over manganese oxide octahedral molecular sieve materials. Journal of Catalysis, 176(2): 321–328
|
| [47] |
Zhou R, Shen N, Zhao J, Su Y, Ren H (2018). Glutathione-coated Fe3O4 nanoparticles with enhanced Fenton-like activity at neutral pH for degrading 2,4-dichlorophenol. Journal of Materials Chemistry A, 6(3): 1275–1283
|
/
| 〈 |
|
〉 |
AI Summary
