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学者姓名:许俊鸽
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Pyrite-driven autotrophic denitrification (PAD) has been recognized as a promising treatment technology for nitrate removal. Although the occurrence of PAD has been found in recent years, there is a knowledge gap about effects of crystal plane of pyrite on the performance and mechanism of PAD system. Here, this study investigated the effects of crystal planes ({100}, {111} and {210}) of single-crystal pyrite on denitrification performance, electron transfer, and microbial mechanism in PAD system. The removal efficiency of nitrate in B-{210} reached 100%, which was 1.67-fold and 2.86-fold higher than that of B-{100} and B-{111}, respectively. X-ray photoelectron spectroscopy and electrochemical results indicated that Fe-S bonds of pyrite with {210} crystal plane were more susceptible to breakage by Fe3+ oxidation assault, and leaching microbially available Fe2+ and sulfur intermediates to drive autotrophic denitrification. Metagenomic results suggested that community of functional pyrite-driven denitrifiers varied in response to crystal plane, and abundances of N-S transformation and EETrelated microbes and genes in B-{210} notably up-regulated compared to B-{100} and B-{111}. In addition, this work proposed a dual-mode for electron transfer pathway during pyrite oxidation and nitrogen transformation in PAD system. In B-{210}, Fe(II)- and sulfur-driven denitrifiers obtained electron after pyrite oxidation-dissolution, and the enrichment of pyrite-oxidizing bacteria in B-{210} could enhance the electron transfer from pyrite through electron shuttles. This work highlighted that stronger surface reactivity and electron shuttle effect in B-{210} enhanced electron transfer, leading to favorable PAD performance in B-{210}. Overall, this study provides novel insights into the structure-activity relationship between the crystal plane structure of pyrite and denitrification activity in PAD system.
Keyword :
Autotrophic denitrification Autotrophic denitrification Crystal plane Crystal plane Electron transfer Electron transfer Metagenome analysis Metagenome analysis Pyrite Pyrite
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GB/T 7714 | Wang, Yingmu , Chen, Shi , Chen, Yuanjing et al. Structure-activity relationship between crystal plane and pyrite-driven autotrophic denitrification efficacy: Electron transfer and metagenome-based microbial mechanism [J]. | WATER RESEARCH , 2025 , 268 . |
MLA | Wang, Yingmu et al. "Structure-activity relationship between crystal plane and pyrite-driven autotrophic denitrification efficacy: Electron transfer and metagenome-based microbial mechanism" . | WATER RESEARCH 268 (2025) . |
APA | Wang, Yingmu , Chen, Shi , Chen, Yuanjing , Xu, Junge , Zhou, Jian , He, Qiang et al. Structure-activity relationship between crystal plane and pyrite-driven autotrophic denitrification efficacy: Electron transfer and metagenome-based microbial mechanism . | WATER RESEARCH , 2025 , 268 . |
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Membrane distillation (MD), boasting high interception efficiency and low operational pressures, emerges as an innovative membrane technology. However, the occurrence of membrane fouling due to interaction between natural organic matter (NOM) and inorganic ions during the MD process curtails water purification efficiency, thereby constraining its potential applications. To address this quandary, this study integrates sulfate radical-based advanced oxidation processes (SR-AOPs) into MD technology to bolster membrane fouling control. A straightforward hydrothermal method coupled with vacuum filtration was employed to synthesize a Co3O4/Nitrogen-modified carbon quantum dots (NCDs)/PVDF (CN-PVDF) membrane for the first time, which was utilized in the MD treatment of simulated humic acid (HA) wastewater. Under visible light irradiation (1.9 kW/m2), CN-PVDF membrane activation of peroxymonosulfate (PMS) effectively altered the chemical attributes of the MD feed solution and reduced organic matter concentration. Moreover, it dismantled the carboxyl sites on HA that interact with Ca2+, consequently attenuating the formation of organic–inorganic complex pollutants. The XDLVO analysis showcased that photo-Fenton oxidation led to a diminishment in pollutant hydrophobicity, correlating with a 17.59 kT reduction in pollutant-membrane adsorption and a 7.47 kT amplification in adhesion barriers. This strategy transformed the initial two-stage fouling mode into a singular one, which significantly decreased the flux decline and the fouling layer thickness. Furthermore, the CN-PVDF membrane demonstrated self-cleaning capabilities via photo-Fenton. This study advances an innovative approach to bolster the fouling resistance of MD membranes and provides substantial theoretical support for the integration of SR-AOPs and MD technologies. © 2024
Keyword :
Biogeochemistry Biogeochemistry Chemicals removal (water treatment) Chemicals removal (water treatment) Distillation Distillation Efficiency Efficiency Membrane fouling Membrane fouling Membrane technology Membrane technology Microfiltration Microfiltration Organic compounds Organic compounds Oxidation Oxidation Semiconductor quantum dots Semiconductor quantum dots Sulfur compounds Sulfur compounds Wastewater treatment Wastewater treatment
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GB/T 7714 | Lu, Zhenyu , Yan, Zhongsen , Chang, Haiqing et al. New insights into antifouling property and interfacial mechanism in photo-Fenton membrane distillation [J]. | Chemical Engineering Journal , 2024 , 492 . |
MLA | Lu, Zhenyu et al. "New insights into antifouling property and interfacial mechanism in photo-Fenton membrane distillation" . | Chemical Engineering Journal 492 (2024) . |
APA | Lu, Zhenyu , Yan, Zhongsen , Chang, Haiqing , Wang, Qiankun , Liu, Fujian , Ni, Qichang et al. New insights into antifouling property and interfacial mechanism in photo-Fenton membrane distillation . | Chemical Engineering Journal , 2024 , 492 . |
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Membrane distillation technology, utilized for treating hypersaline wastewater from seawater desalination, often encounters challenges related to inorganic scaling, adversely affecting membrane performance. Herein, we introduce a innovative approach employing a sacrificial layer on the surface of Thin Film Composite (TFC) membranes to concurrently enhance inorganic scaling resistance and facilitate membrane reusability. The sacrificial layer (Fe3+-TA) consisted of tannic acid (TA) complexed with iron ions (Fe3+) and could be removed and regenerated in situ. The results demonstrated that the Fe3+-TA layer significantly improved the membrane's surface smoothness and densification, maintaining superior anti-scaling performance. The modified membrane exhibited remarkable durability, sustaining six reuse cycles with a flux recovery exceeding 97 % in gypsum scaling tests. Furthermore, the formation of new complexes during gypsum scaling tests confirmed the membrane's augmented scaling retardation capabilities. Thus, integrating of a sacrificial layer into TFC membranes presents a promising strategy for advancing membrane distillation processes in hypersaline wastewater treatment. © 2024 Elsevier B.V.
Keyword :
Anti-scaling Anti-scaling Inorganic scaling Inorganic scaling Membrane distillation Membrane distillation Reuse Reuse Sacrificial protective layer Sacrificial protective layer
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GB/T 7714 | Yan, Z. , Lin, S. , Chang, H. et al. Functional of thin-film composite Janus membrane with sacrificial layer for inorganic scaling control in membrane distillation [J]. | Journal of Membrane Science , 2024 , 710 . |
MLA | Yan, Z. et al. "Functional of thin-film composite Janus membrane with sacrificial layer for inorganic scaling control in membrane distillation" . | Journal of Membrane Science 710 (2024) . |
APA | Yan, Z. , Lin, S. , Chang, H. , Xu, J. , Dai, W. , Qu, D. et al. Functional of thin-film composite Janus membrane with sacrificial layer for inorganic scaling control in membrane distillation . | Journal of Membrane Science , 2024 , 710 . |
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Membrane distillation technology, utilized for treating hypersaline wastewater from seawater desalination, often encounters challenges related to inorganic scaling, adversely affecting membrane performance. Herein, we introduce a innovative approach employing a sacrificial layer on the surface of Thin Film Composite (TFC) membranes to concurrently enhance inorganic scaling resistance and facilitate membrane reusability. The sacrificial layer (Fe3+-TA) 3 +-TA) consisted of tannic acid (TA) complexed with iron ions (Fe3+) 3 + ) and could be removed and regenerated in situ. The results demonstrated that the Fe3+-TA 3 +-TA layer significantly improved the membrane's surface smoothness and densification, maintaining superior anti-scaling performance. The modified membrane exhibited remarkable durability, sustaining six reuse cycles with a flux recovery exceeding 97 % in gypsum scaling tests. Furthermore, the formation of new complexes during gypsum scaling tests confirmed the membrane's augmented scaling retardation capabilities. Thus, integrating of a sacrificial layer into TFC membranes presents a promising strategy for advancing membrane distillation processes in hypersaline wastewater treatment.
Keyword :
Anti-scaling Anti-scaling Inorganic scaling Inorganic scaling Membrane distillation Membrane distillation Reuse Reuse Sacrificial protective layer Sacrificial protective layer
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GB/T 7714 | Yan, Zhongsen , Lin, Sufen , Chang, Haiqing et al. Functional of thin-film composite Janus membrane with sacrificial layer for inorganic scaling control in membrane distillation [J]. | JOURNAL OF MEMBRANE SCIENCE , 2024 , 710 . |
MLA | Yan, Zhongsen et al. "Functional of thin-film composite Janus membrane with sacrificial layer for inorganic scaling control in membrane distillation" . | JOURNAL OF MEMBRANE SCIENCE 710 (2024) . |
APA | Yan, Zhongsen , Lin, Sufen , Chang, Haiqing , Xu, Junge , Dai, Wenxin , Qu, Dan et al. Functional of thin-film composite Janus membrane with sacrificial layer for inorganic scaling control in membrane distillation . | JOURNAL OF MEMBRANE SCIENCE , 2024 , 710 . |
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Iron-based catalysts have been widely used to treat refractory organic pollutants in wastewater.In this paper,magnetic Co-γ-Fe2O3 was synthesized by a facile tartaric acid-assisted hydrothermal method,and Co-γ-Fe2O3/MoS2 nanocomposite catalyst was obtained via in situ growth of MoS2 nanosheets on Co-γ-Fe2O3 nanoparticles.The nanocomposite catalysts were used to decompose bisphenol A(BPA)by activating peroxymonosulfate(PMS).It was shown that only 0.15 g/L catalyst and 0.5 mmol/L PMS degraded 10 mg/L of BPA(99.3%within 10 min)in the pH range of 3-9.PMS was activated due to redox cycling among the pairs Co(Ⅲ)/Co(Ⅱ),Fe(Ⅲ)/Fe(Ⅱ),and Mo(Ⅵ)/Mo(Ⅳ).Quenching experiments and electron paramagnetic resonance spectroscopy demonstrated that both radical and non-radical pathways were involved in BPA degradation,in which active radical sulfate radical and non-radical singlet oxygen were the main reactive oxygen species.Ten intermediates were identified by liquid chromatography-coupled mass spectrometry,and three possible BPA degradation pathways were proposed.The toxicity of several degradation intermediates was lower,and Co-γ-Fe2O3/MoS2 exhibited excellent reusability and could be magnetically recovered.
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GB/T 7714 | Junge Xu , Dong Wang , Die Hu et al. Magnetic Co-doped 1D/2D structured γ-Fe2O3/MoS2 effectively activated peroxymonosulfate for efficient abatement of bisphenol A via both radical and non-radical pathways [J]. | 环境科学与工程前沿 , 2024 , 18 (3) : 143-159 . |
MLA | Junge Xu et al. "Magnetic Co-doped 1D/2D structured γ-Fe2O3/MoS2 effectively activated peroxymonosulfate for efficient abatement of bisphenol A via both radical and non-radical pathways" . | 环境科学与工程前沿 18 . 3 (2024) : 143-159 . |
APA | Junge Xu , Dong Wang , Die Hu , Ziwei Zhang , Junhong Chen , Yingmu Wang et al. Magnetic Co-doped 1D/2D structured γ-Fe2O3/MoS2 effectively activated peroxymonosulfate for efficient abatement of bisphenol A via both radical and non-radical pathways . | 环境科学与工程前沿 , 2024 , 18 (3) , 143-159 . |
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Membrane distillation (MD), boasting high interception efficiency and low operational pressures, emerges as an innovative membrane technology. However, the occurrence of membrane fouling due to interaction between natural organic matter (NOM) and inorganic ions during the MD process curtails water purification efficiency, thereby constraining its potential applications. To address this quandary, this study integrates sulfate radicalbased advanced oxidation processes (SR-AOPs) into MD technology to bolster membrane fouling control. A straightforward hydrothermal method coupled with vacuum filtration was employed to synthesize a Co3O4/ Nitrogen-modified carbon quantum dots (NCDs)/PVDF (CN-PVDF) membrane for the first time, which was utilized in the MD treatment of simulated humic acid (HA) wastewater. Under visible light irradiation (1.9 kW/ m2), CN-PVDF membrane activation of peroxymonosulfate (PMS) effectively altered the chemical attributes of the MD feed solution and reduced organic matter concentration. Moreover, it dismantled the carboxyl sites on HA that interact with Ca2+, consequently attenuating the formation of organic-inorganic complex pollutants. The XDLVO analysis showcased that photo-Fenton oxidation led to a diminishment in pollutant hydrophobicity, correlating with a 17.59 kT reduction in pollutant-membrane adsorption and a 7.47 kT amplification in adhesion barriers. This strategy transformed the initial two-stage fouling mode into a singular one, which significantly decreased the flux decline and the fouling layer thickness. Furthermore, the CN-PVDF membrane demonstrated self-cleaning capabilities via photo-Fenton. This study advances an innovative approach to bolster the fouling resistance of MD membranes and provides substantial theoretical support for the integration of SR-AOPs and MD technologies.
Keyword :
control control Membrane distillation Membrane distillation Membrane fouling Membrane fouling Self-cleaning Self-cleaning
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GB/T 7714 | Lu, Zhenyu , Yan, Zhongsen , Chang, Haiqing et al. New insights into antifouling property and interfacial mechanism in photo-Fenton membrane distillation [J]. | CHEMICAL ENGINEERING JOURNAL , 2024 , 492 . |
MLA | Lu, Zhenyu et al. "New insights into antifouling property and interfacial mechanism in photo-Fenton membrane distillation" . | CHEMICAL ENGINEERING JOURNAL 492 (2024) . |
APA | Lu, Zhenyu , Yan, Zhongsen , Chang, Haiqing , Wang, Qiankun , Liu, Fujian , Ni, Qichang et al. New insights into antifouling property and interfacial mechanism in photo-Fenton membrane distillation . | CHEMICAL ENGINEERING JOURNAL , 2024 , 492 . |
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Pollution from extensive sulfonamide antibiotic use is a critical research focus, particularly in the remediation of these antibiotics using composite materials. This study employed a CuFe2O4/ZIF-8 composite to activate sodium percarbonate (SPC) for the photo-Fenton-like degradation of the sulfonamide antibiotic sulfamethoxazole (SMX). The optimal conditions for SMX degradation were determined using the CuFe2O4/ZIF-8/SPC/Vis system: a ZIF-8 composite ratio of 40 %, catalyst dosage of 0.15 g/L, SPC concentration of 0.8 mM, and initial pH of 3.0, achieving complete SMX removal within 30 min. After five cycle tests, the leaching rates of copper and iron ions were 0.179 mg/L and 0.376 mg/L, respectively, significantly lower compared to the use of CuFe2O4 alone as the catalyst (Cu: 0.46 mg/L, Fe: 1.43 mg/L). The radicals present in the system were identified, with their contribution rates ranked from highest to lowest as follows: OH > h(+)> O-2(-) > CO3(-) > O-1(2). Further mechanistic investigations revealed that the heterogeneous structures in CuFe2O4/ZIF-8 enhanced the efficiency of the photo-Fenton-like reaction by facilitating electron transfer. This study introduced an innovative approach for antibiotic treatment using the CuFe2O4/ZIF-8 composite under visible light irradiation and broadened the technical framework of SPC-based advanced oxidation processes (AOPs) for treating wastewater.
Keyword :
CuFe2O4/ZIF-8 CuFe2O4/ZIF-8 Heterogeneous photo-Fenton-like Heterogeneous photo-Fenton-like Magnetic recovery Magnetic recovery Sodium percarbonate Sodium percarbonate Sulfonamide antibiotics Sulfonamide antibiotics
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GB/T 7714 | Xu, Junge , Yu, Weihao , Zhang, Ziwei et al. Rhombic dodecahedral ZIF-8-supported CuFe2O4 triggers sodium percarbonate activation for enhanced sulfonamide antibiotics degradation: Synergistic roles of heterostructure and photocatalytic mechanisms [J]. | CHEMICAL ENGINEERING JOURNAL , 2024 , 501 . |
MLA | Xu, Junge et al. "Rhombic dodecahedral ZIF-8-supported CuFe2O4 triggers sodium percarbonate activation for enhanced sulfonamide antibiotics degradation: Synergistic roles of heterostructure and photocatalytic mechanisms" . | CHEMICAL ENGINEERING JOURNAL 501 (2024) . |
APA | Xu, Junge , Yu, Weihao , Zhang, Ziwei , Deng, Fubin , Wang, Shengkong , Zou, Rusen et al. Rhombic dodecahedral ZIF-8-supported CuFe2O4 triggers sodium percarbonate activation for enhanced sulfonamide antibiotics degradation: Synergistic roles of heterostructure and photocatalytic mechanisms . | CHEMICAL ENGINEERING JOURNAL , 2024 , 501 . |
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Iron-based catalysts have been widely used to treat refractory organic pollutants in wastewater. In this paper, magnetic Co-gamma-Fe(2)O(3 )was synthesized by a facile tartaric acid-assisted hydrothermal method, and Co-gamma-Fe2O3/MoS2 nanocomposite catalyst was obtained via in situ growth of MoS2 nanosheets on Co-gamma-Fe2O3 nanoparticles. The nanocomposite catalysts were used to decompose bisphenol A (BPA) by activating peroxymonosulfate (PMS). It was shown that only 0.15 g/L catalyst and 0.5 mmol/L PMS degraded 10 mg/L of BPA (99.3% within 10 min) in the pH range of 3-9. PMS was activated due to redox cycling among the pairs Co(III)/Co(II), Fe(III)/Fe(II), and Mo(VI)/Mo(IV). Quenching experiments and electron paramagnetic resonance spectroscopy demonstrated that both radical and non-radical pathways were involved in BPA degradation, in which active radical sulfate radical and non-radical singlet oxygen were the main reactive oxygen species. Ten intermediates were identified by liquid chromatography-coupled mass spectrometry, and three possible BPA degradation pathways were proposed. The toxicity of several degradation intermediates was lower, and Co-gamma-Fe2O3/MoS2 exhibited excellent reusability and could be magnetically recovered.
Keyword :
Bisphenol A Bisphenol A Degradation pathways Degradation pathways Hydrothermal method Hydrothermal method Magnetic Co-gamma-Fe2O3/MoS2 Magnetic Co-gamma-Fe2O3/MoS2 Toxicity analysis Toxicity analysis
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GB/T 7714 | Xu, Junge , Wang, Dong , Hu, Die et al. Magnetic Co-doped 1D/2D structured γ-Fe2O3/MoS2 effectively activated peroxymonosulfate for efficient abatement of bisphenol A via both radical and non-radical pathways [J]. | FRONTIERS OF ENVIRONMENTAL SCIENCE & ENGINEERING , 2024 , 18 (3) . |
MLA | Xu, Junge et al. "Magnetic Co-doped 1D/2D structured γ-Fe2O3/MoS2 effectively activated peroxymonosulfate for efficient abatement of bisphenol A via both radical and non-radical pathways" . | FRONTIERS OF ENVIRONMENTAL SCIENCE & ENGINEERING 18 . 3 (2024) . |
APA | Xu, Junge , Wang, Dong , Hu, Die , Zhang, Ziwei , Chen, Junhong , Wang, Yingmu et al. Magnetic Co-doped 1D/2D structured γ-Fe2O3/MoS2 effectively activated peroxymonosulfate for efficient abatement of bisphenol A via both radical and non-radical pathways . | FRONTIERS OF ENVIRONMENTAL SCIENCE & ENGINEERING , 2024 , 18 (3) . |
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Excessive discharge of nutrients from wastewater treatment plants (WWTPs) is an important pollutant source of eutrophic water bodies. In this work, three electrochemically integrated horizontal flow constructed wetlands (E-HFCWs) were developed for advanced nutrients removal from WWTPs effluent with different S/N ratios. In E-HFCWs, PO43-, NO3--N and TN removal percentages at current of 0.2 A and hydraulic retention time (HRT) of 24 h did not differ significantly as S/N ratios altered. When fed with low, middle and high concentrations of SO42--S wastewater during this period, PO43--P removal percentages respectively reached 99.3 %+/- 0.9 %, 99.2 %+/- 1.1 % and 99.0 %+/- 1.4 %, NO3--N removal percentages respectively reached 99.5 %+/- 0.5 %, 99.6 %+/- 0.4 % and 99.4 %+/- 0.8 %, and TN removal percentages respectively reached 92.0 %+/- 2.5 %, 90.8 %+/- 3.4 % and 91.2 %+/- 2.7 %. This work highlighted that sulfur cycle played crucial roles in improving nitrogen removal stability as current or HRT decreased in higher S/N ratio groups. The formed sulfur ferrites under higher current or HRT condition served as "electron reservoir", and would resupply electron for denitrification when electron supplied by electrolysis was deficient. In addition, the higher S/N ratio groups allowed significantly lower N2O accumulation, which was accordance with the concept of carbon neutral. Based on metagenome results, the occurrence of more abundant sulfur-oxidizing denitrifying genes and bacteria (e.g., Thiobacillus) in higher S/N ratio groups under lower current or HRT further demonstrated the significant roles of sulfur cycle in stable autotrophic denitrification performance in E-HFCWs. Overall, this work provides perspective on the future practical application for the regulation of nitrogen removal stability enhancement and N2O emission reduction in electrochemically integrated bioreactors.
Keyword :
Autotrophic denitrification Autotrophic denitrification Biological nutrients removal Biological nutrients removal Constructed wetlands Constructed wetlands Metagenome analysis Metagenome analysis Tertiary treatment Tertiary treatment
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GB/T 7714 | Wang, Yingmu , Xie, Shikang , Zhou, Jian et al. Sulfur cycle contributes to stable autotrophic denitrification and lower N2O accumulation in electrochemically integrated constructed wetlands: Electron transfers patterns and metagenome insights [J]. | CHEMICAL ENGINEERING JOURNAL , 2023 , 451 . |
MLA | Wang, Yingmu et al. "Sulfur cycle contributes to stable autotrophic denitrification and lower N2O accumulation in electrochemically integrated constructed wetlands: Electron transfers patterns and metagenome insights" . | CHEMICAL ENGINEERING JOURNAL 451 (2023) . |
APA | Wang, Yingmu , Xie, Shikang , Zhou, Jian , Fan, Gongduan , He, Lei , Fan, Xing et al. Sulfur cycle contributes to stable autotrophic denitrification and lower N2O accumulation in electrochemically integrated constructed wetlands: Electron transfers patterns and metagenome insights . | CHEMICAL ENGINEERING JOURNAL , 2023 , 451 . |
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Trimethoprim (TMP), as a widely used chemotherapeutic antibiotic agent, has caused potential risks to the aquatic environment. In this study, magnetic Co-doped Fe3O4/alpha-FeOOH was fabricated by a facile one-step ageing method and used for activation of peroxymonosulfate (PMS) in TMP degradation. It was found that low catalyst (0.5 g/L) and PMS addition (0.2 mM) led to the high degradation efficiency of TMP (97.2%, k(obs) = 0.11211 min(-1)) over a wide range of pH. The oxidation of active radical (SO4 center dot(-)) and non-radical singlet oxygen (O-1(2)) co-acted on TMP degradation. Besides, PMS was activated through the cycles between Co(II)/Co(III) and Fe (II)/Fe(III). Fifteen degradation intermediates of TMP were identified by LC-MS, and three possible degradation pathways including hydroxylation, demethylation, and cleavage were proposed. The recovered catalysts exhibited high stability and reusability, maintaining 80% TMP removal efficiency with inappreciable metal leaching (0.012 mg/L of Co, 0.113 mg/L of Fe) after six cycles. Besides, the Co-Fe3O4/alpha-FeOOH/PMS system was highly tolerant to inorganic anions and actual water bodies (river water, lake water, tap water, and sewage plant effluent). Overall, this work provided a promising way to the potential application of Fe-based binary metal oxide for PMS activation.
Keyword :
Advanced oxidation process Advanced oxidation process Antibiotic Antibiotic Degradation pathways Degradation pathways Magnetic recovery Magnetic recovery PMS activation PMS activation
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GB/T 7714 | Xu, Junge , Zhang, Ziwei , Hong, Junxian et al. Co-doped Fe3O4/alpha-FeOOH for highly efficient peroxymonosulfate activation to degrade trimethoprim: Occurrence of hybrid non-radical and radical pathways [J]. | JOURNAL OF ENVIRONMENTAL MANAGEMENT , 2023 , 325 . |
MLA | Xu, Junge et al. "Co-doped Fe3O4/alpha-FeOOH for highly efficient peroxymonosulfate activation to degrade trimethoprim: Occurrence of hybrid non-radical and radical pathways" . | JOURNAL OF ENVIRONMENTAL MANAGEMENT 325 (2023) . |
APA | Xu, Junge , Zhang, Ziwei , Hong, Junxian , Wang, Dong , Fan, Gongduan , Zhou, Jian et al. Co-doped Fe3O4/alpha-FeOOH for highly efficient peroxymonosulfate activation to degrade trimethoprim: Occurrence of hybrid non-radical and radical pathways . | JOURNAL OF ENVIRONMENTAL MANAGEMENT , 2023 , 325 . |
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