Synthesis of magnetically separable MnO2/Fe3O4/silica nanofiber composite with enhanced Fenton-like catalytic activity for degradation of Acid Red 73

Tang, Xuekun; Huang, Jing; Liu, Kun; Feng, Qiming; Li, Zishun; Ao, Minlin

doi:10.1016/j.surfcoat.2018.09.011

Cited by 30 publications

(30 citation statements)

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“…MnO 2 ‐based materials have shown enormous potential applications in the removal of organic pollutants in various wastewater treatment technologies, including adsorption, catalytic ozonation, photocatalytic oxidation, electrocatalytic oxidation, peroxymonosulfate oxidation, catalytic filtration, and energy harvesting galvanic cell technologies. So far, MnO 2 ‐based materials have shown superior performances in the removal of various organic pollutants in water, such as dye (methylene blue, [ 359–361 ] methyl orange, [ 362,363 ] Rhodamine B, [ 309,364 ] Congo red, [ 365 ] acid fuchsin dye, [ 218 ] crystal violet dye, [ 366 ] acid red 73, [ 367 ] neutral red, [ 368 ] and tartrazin yellow [ 369 ] ), phenolic pharmaceuticals (phenol, [ 66,325,342,370–372 ] bisphenol A, [ 99,275,373–378 ] ibuprofen, [ 295 ] tetrabromobisphenol A, [ 379 ] benzophenone‐3, [ 216 ] 2,4‐dichlorophenol, [ 380 ] 4‐chlorophenol, [ 381 ] and 4‐nitrophenol [ 382 ] ), antibiotics (tetracycline, [ 383 ] ceftiofur, [ 243 ] and lomefloxacin [ 243 ] ), as well as ammonia borane, [ 384 ] amides, [ 385 ] lignin, [ 386 ] peroxymonosulfate, [ 237 ] 17 β‐Estradiol, [ 249 ] m ‐aminophenol, [ 387 ] carbamazepine, [ 388 ] dichloroacetic acid, [ 389 ] p ‐arsanilic acid, [ 390 ] phenylarsonic acids, [ 391 ] m ‐cresol, [ 288 ] oxalic acid, [ 392 ] ciprofloxacin, [ 393,394 ] phenanthrene, [ 246 ] norfloxacin, [ 291 ] etc. ( Table 2 ).…”

Section: Environmental Applicationsmentioning

confidence: 99%

MnO₂‐Based Materials for Environmental Applications

et al. 2021

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Manganese dioxide (MnO2) is a promising photo–thermo–electric‐responsive semiconductor material for environmental applications, owing to its various favorable properties. However, the unsatisfactory environmental purification efficiency of this material has limited its further applications. Fortunately, in the last few years, significant efforts have been undertaken for improving the environmental purification efficiency of this material and understanding its underlying mechanism. Here, the aim is to summarize the recent experimental and computational research progress in the modification of MnO2 single species by morphology control, structure construction, facet engineering, and element doping. Moreover, the design and fabrication of MnO2‐based composites via the construction of homojunctions and MnO2/semiconductor/conductor binary/ternary heterojunctions is discussed. Their applications in environmental purification systems, either as an adsorbent material for removing heavy metals, dyes, and microwave (MW) pollution, or as a thermal catalyst, photocatalyst, and electrocatalyst for the degradation of pollutants (water and gas, organic and inorganic) are also highlighted. Finally, the research gaps are summarized and a perspective on the challenges and the direction of future research in nanostructured MnO2‐based materials in the field of environmental applications is presented. Therefore, basic guidance for rational design and fabrication of high‐efficiency MnO2‐based materials for comprehensive environmental applications is provided.

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Section: Environmental Applicationsmentioning

confidence: 99%

MnO₂‐Based Materials for Environmental Applications

et al. 2021

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“…Many results show that the smaller the size of the catalyst particles, the larger the specific surface area, the more surface defects and the higher the catalytic activity [43]. The X-ray photoelectron spectroscopy (XPS) provides information about elemental composition and valence state of sample surface [19,44], so the XPS was used to study above three kinds of MgO with different particle sizes. Figure 7 shows the XPS spectra of MgO at 50 nm (a and b), MgO at 1 µm (c and d), and MgO at 10 µm (e and f).…”

Section: Effect Of Hydroxyl and Oxygen Vacancy In The Mgo Surface On mentioning

confidence: 99%

“…Liu's group catalyzed PMS by supporting Fe 3 O 4 nanoparticles and nanoflower-like MnO 2 layer by layer on the surface of porous diatomite or silica nanofiber. The high specific area of the core-shell nanocomposites made it easier for PMS and organic pollutants to contact with the catalysts, and the synergistic effect between MnO 2 and Fe 3 O 4 increased the activation performance of the catalysts [8,19,20]. Huang's group reported iron-copper bimetal doped mesoporous g-Al 2 O 3 catalyzed PMS to effectively degrade 4-chlorophenol, finding that the Al-O-Fe and Al-O-Cu bonds formed by Fe and Cu doping into the framework of g-Al 2 O 3 were the key structures for high activity of the catalyst [21].…”

Section: Introductionmentioning

confidence: 99%

High-Efficiency Catalysis of Peroxymonosulfate by MgO for the Degradation of Organic Pollutants

et al. 2019

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In the study, magnesium oxide (MgO) was used to catalyze peroxymonosulfate (PMS) for the degradation of organic pollutants for the first time. According to the single-factor experiment results, it was determined that MgO could efficiently catalyze PMS to degrade organic matters in a wide range of pH values. Based on radical quenching experiments and electron spinning resonance spectra, singlet oxygen was identified to be the crucial reactive species. Importantly, the oxygen vacancy on the surface of MgO was determined as the key active site, which accelerated the decomposition of PMS to produce singlet oxygen. This study provides an interesting insight into the novel and ignored catalyst of MgO for the highly efficient activation of PMS, which will greatly benefit the Fenton-like catalytic degradation of organic wastewater.

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“…Among the developed activation methods, transitional metal-containing catalysts (e.g., M = Ag, Fe, Mn, Co, and V) were considered as promising routes without energy inputs [as presented in Eq. 2] [10,11]. Although transition metal-containing catalysts have achieved good degradation efficiency, their practical applications are limited because of the secondary pollution of dissolved transition metals in the process [12,13].…”

Section: Introductionmentioning

confidence: 99%

A novel carbon nanotube–magnesium oxide composite with excellent recyclability to efficiently activate peroxymonosulfate for Rhodamine B degradation

et al. 2020

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There is an urgent need for an eco-friendly and efficient route to treat the organic pollutants in wastewater. Therefore, we report a facile synthesis of carbon nanotube-magnesium oxide composite (CNTs/MgO) which can efficiently activate peroxymonosulfate (PMS) to degrade Rhodamine B (RhB). Fabricated CNTs/MgO was characterized by XRD, FTIR, SEM, TEM, BET, XPS, and Raman. The results showed that the carbon nanotubes uniformly entangled on the MgO whiskers and linked to the MgO by Mg-C and CO bonds. The effects of temperature, pH value, CNTs/MgO dosage, PMS dosage and the ratio of MgO/CNTs on degradation of RhB were conducted to determine the activation performance of CNTs/MgO. The catalytic degradation process was carried out in a wide pH range of 3-9, and 100% of RhB was degraded in 20 min under optimized conditions. Moreover, the efficient degradation performance was attributed to singlet oxygen generated in the PMS&CNTs/MgO system. The excellent activation properties of CNTs/MgO was derived from the enhanced electron transport performance and chemical bonding between MgO and CNTs. In addition, this work provides an innovative design for the development of novel PMS catalysts without transition metal components.

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Synthesis of magnetically separable MnO2/Fe3O4/silica nanofiber composite with enhanced Fenton-like catalytic activity for degradation of Acid Red 73

Cited by 30 publications

References 40 publications

MnO₂‐Based Materials for Environmental Applications

MnO₂‐Based Materials for Environmental Applications

High-Efficiency Catalysis of Peroxymonosulfate by MgO for the Degradation of Organic Pollutants

A novel carbon nanotube–magnesium oxide composite with excellent recyclability to efficiently activate peroxymonosulfate for Rhodamine B degradation

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Synthesis of magnetically separable MnO2/Fe3O4/silica nanofiber composite with enhanced Fenton-like catalytic activity for degradation of Acid Red 73

Cited by 30 publications

References 40 publications

MnO2‐Based Materials for Environmental Applications

MnO2‐Based Materials for Environmental Applications

High-Efficiency Catalysis of Peroxymonosulfate by MgO for the Degradation of Organic Pollutants

A novel carbon nanotube–magnesium oxide composite with excellent recyclability to efficiently activate peroxymonosulfate for Rhodamine B degradation

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Product

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MnO₂‐Based Materials for Environmental Applications

MnO₂‐Based Materials for Environmental Applications