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学者姓名:汤湘
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Anaerobic fermentation is an attractive energy production process that contributes to decarbonizing the economy and addresses climate change while successfully managing organic waste. However, its effectiveness is significantly hindered by its inherent electronic effect-the formation of organic-metal complexes elevates the energy required for microbial degradation. Here, this study demonstrated that zeolite can be used as a cost-effective and reusable ion exchange medium to selectively extract cations from the waste activated sludge (WAS) matrix, thereby disrupting organic-metal complexes and enhancing the recovery of short-chain fatty acids (SCFAs) during anaerobic fermentation. Compared with untreated samples, the addition of zeolite (2.0 g/g TSS, 2 days) resulted in a 3.61-fold increase in SCFAs production. Meanwhile, zeolite has excellent ion exchange capacity (after the first and second reuse, the SCFAs production reached 71.42% and 68.00% of the initial levels, respectively) and renewability (following regeneration with 1.0 M NaCl (pH = 11), the SCFAs production reached 94.46% of initial levels). Metatranscriptomics analysis showed that zeolite increased the expression of functional genes involved in hydrolysis and acidogenesis processes. Specifically, the expression of genes encoding the glycoside hydrolase family 97 and acetate CoA-transferase increased by 1.34-fold and 3.66-fold, respectively. This study demonstrates the feasibility of zeolite in mitigating electronic effect and presents a promising strategy for sustainable and cost-effective recovery of SCFAs from WAS.
Keyword :
Anaerobic fermentation Anaerobic fermentation Electronic effect Electronic effect Short-chain fatty acids Short-chain fatty acids Waste activated sludge Waste activated sludge Zeolite Zeolite
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| GB/T 7714 | Xiao, Huannian , Zhang, Baowei , Zhong, Linrui et al. Enhancing the recovery of short-chain fatty acids from waste activated sludge through zeolite-mediated mitigation of electronic effect [J]. | SEPARATION AND PURIFICATION TECHNOLOGY , 2025 , 364 . |
| MLA | Xiao, Huannian et al. "Enhancing the recovery of short-chain fatty acids from waste activated sludge through zeolite-mediated mitigation of electronic effect" . | SEPARATION AND PURIFICATION TECHNOLOGY 364 (2025) . |
| APA | Xiao, Huannian , Zhang, Baowei , Zhong, Linrui , Wang, Ruobin , Ran, Zezhong , Wei, Mengqi et al. Enhancing the recovery of short-chain fatty acids from waste activated sludge through zeolite-mediated mitigation of electronic effect . | SEPARATION AND PURIFICATION TECHNOLOGY , 2025 , 364 . |
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Five small interfering RNA (siRNA)-based therapeutics have been approved by the Food and Drug Administration (FDA), namely patisiran, givosiran, lumasiran, inclisiran, and vutrisiran. Besides, siRNA delivery to the target site without toxicity is a big challenge for researchers, and naked-siRNA delivery possesses several challenges, including membrane impermeability, enzymatic degradation, mononuclear phagocyte system (MPS) entrapment, fast renal excretion, endosomal escape, and off-target effects. The siRNA therapeutics can silence any disease-specific gene, but their intracellular and extracellular barriers limit their clinical applications. For this purpose, several modifications have been employed to siRNA for better transfection efficiency. Still, there is a quest for better delivery systems for siRNA delivery to the target site. In recent years, nanoparticles have shown promising results in siRNA delivery with minimum toxicity and off-target effects. Patisiran is a lipid nanoparticle (LNP)-based siRNA formulation for treating hereditary transthyretin-mediated amyloidosis that ultimately warrants the use of nanoparticles from different classes, especially lipid-based nanoparticles. These nanoparticles may belong to different categories, including lipid-based, polymer-based, and inorganic nanoparticles. This review briefly discusses the lipid, polymer, and inorganic nanoparticles and their sub-types for siRNA delivery. Finally, several clinical trials related to siRNA therapeutics are addressed, followed by the future prospects and conclusions.
Keyword :
Antibiotics resistant bacteria Antibiotics resistant bacteria Antibiotics resistant genes Antibiotics resistant genes Photocatalytic oxidation Photocatalytic oxidation
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| GB/T 7714 | Guo, Zicong , Tang, Xiang , Wang, Wenjun et al. The photo-based treatment technology simultaneously removes resistant bacteria and resistant genes from wastewater [J]. | JOURNAL OF ENVIRONMENTAL SCIENCES , 2025 , 148 : 243-262 . |
| MLA | Guo, Zicong et al. "The photo-based treatment technology simultaneously removes resistant bacteria and resistant genes from wastewater" . | JOURNAL OF ENVIRONMENTAL SCIENCES 148 (2025) : 243-262 . |
| APA | Guo, Zicong , Tang, Xiang , Wang, Wenjun , Luo, Zhangxiong , Zeng, Yuxi , Zhou, Nan et al. The photo-based treatment technology simultaneously removes resistant bacteria and resistant genes from wastewater . | JOURNAL OF ENVIRONMENTAL SCIENCES , 2025 , 148 , 243-262 . |
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The pronounced enrichment of cadmium (Cd) in waste activated sludge (WAS) presents dual environmental challenges through its elevated leaching risks and inhibitory effects on subsequent anaerobic digestion (AD) processes, thereby hindering the safe and sustainable management of sludge. While cadmium sulfide (CdS) as a semiconductor has evidenced photostimulated AD enhancement capabilities, critical challenges persist in simultaneously stabilizing Cd2 + into CdS and improving resource recovery within complex sludge matrices. This study introduces a novel strategy for managing Cd-containing waste activated sludge (WAS) by employing a light-assisted AD process following alkali pretreatment. This approach achieved a methane yield of 111.0 +/- 2.2 L CH4/kg VSS, significantly outperforming conventional (dark) AD (27.1 +/- 1.2 L CH4/kg VSS) and AD with alkali pretreatment only (46.4 +/- 1.6 CH4/kg VSS). The alkali pretreatment disrupted the extracellular polymeric substances in the sludge, promoting direct contact between CdS particles and microorganisms, thereby strengthening methanogenic electron capture. Electrochemical analysis corroborated the enhanced electron transfer, further validated by metatranscriptomic evidence that revealed upregulated expression of electron transfer pathways in the microbial community. This study introduces an innovative framework for optimizing AD performance in Cd-containing WAS, offering valuable insights into the efficient treatment of heavy metal-laden sludge and advancing the sustainable utilization of sludge-derived resources.
Keyword :
Anaerobic digestion Anaerobic digestion Cadmium sulfide Cadmium sulfide Electron transfer Electron transfer Microbial-semiconductor biohybrid Microbial-semiconductor biohybrid Waste activated sludge Waste activated sludge
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| GB/T 7714 | Zhang, Baowei , Tang, Xiang , Zhong, Linrui et al. CdS-mediated electron dynamics in light-assisted anaerobic digestion: Simultaneous cadmium sequestration and methane enrichment by alkali pretreatment [J]. | JOURNAL OF HAZARDOUS MATERIALS , 2025 , 496 . |
| MLA | Zhang, Baowei et al. "CdS-mediated electron dynamics in light-assisted anaerobic digestion: Simultaneous cadmium sequestration and methane enrichment by alkali pretreatment" . | JOURNAL OF HAZARDOUS MATERIALS 496 (2025) . |
| APA | Zhang, Baowei , Tang, Xiang , Zhong, Linrui , Zheng, Jiangfu , Xiao, Huannian , Deng, Yizhan et al. CdS-mediated electron dynamics in light-assisted anaerobic digestion: Simultaneous cadmium sequestration and methane enrichment by alkali pretreatment . | JOURNAL OF HAZARDOUS MATERIALS , 2025 , 496 . |
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BackgroundAntimicrobial resistance poses a substantial and growing threat to global health. While antibiotic resistance genes (ARGs) are tracked most closely in clinical settings, their spread remains poorly understood in non-clinical environments. Mitigating the spread of ARGs in non-clinical contexts such as soil could limit their enrichment in food webs.ResultsMulti-omics (involving metagenomics, metatranscriptomics, viromics, and metabolomics) and direct experimentation show that targeting keystone bacterial taxa by phages can limit ARG maintenance and dissemination in natural soil environments. Based on the metagenomic analysis, we first show that phages from activated sludge can regulate soil microbiome composition and function in terms of reducing ARG abundances and changing the bacterial community composition. This effect was mainly driven by a reduction in the abundance and activity of Streptomyces genus, which is well known for encoding both antibiotic resistance and synthesis genes. To validate the significance of this keystone species for the loss of ARGs, we enriched phage consortia specific to Streptomyces and tested their effect on ARG abundances on 48 soil samples collected across China. We observed a consistent reduction in ARG abundances across all soils, confirming that Streptomyces-enriched phages could predictably change the soil microbiome resistome and mitigate the prevalence of ARGs. This study highlights that phages can be used as ecosystem engineers to control the spread of antibiotic resistance in the environment.ConclusionOur study demonstrates that some bacterial keystone taxa are critical for ARG maintenance and dissemination in soil microbiomes, and opens new ecological avenues for microbiome modification and resistome control. This study advances our understanding of how metagenomics-informed phage consortia can be used to predictably regulate soil microbiome composition and functioning by targeting keystone bacterial taxa.3cmU8RStwhfZ94ahX7b_G7Video AbstractConclusionOur study demonstrates that some bacterial keystone taxa are critical for ARG maintenance and dissemination in soil microbiomes, and opens new ecological avenues for microbiome modification and resistome control. This study advances our understanding of how metagenomics-informed phage consortia can be used to predictably regulate soil microbiome composition and functioning by targeting keystone bacterial taxa.3cmU8RStwhfZ94ahX7b_G7Video Abstract
Keyword :
Antibiotic resistance Antibiotic resistance Farmland soil Farmland soil Keystone taxa Keystone taxa Metagenomics and viromics Metagenomics and viromics Phage community Phage community
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| GB/T 7714 | Liao, Hanpeng , Wen, Chang , Huang, Dan et al. Harnessing phage consortia to mitigate the soil antibiotic resistome by targeting keystone taxa Streptomyces [J]. | MICROBIOME , 2025 , 13 (1) . |
| MLA | Liao, Hanpeng et al. "Harnessing phage consortia to mitigate the soil antibiotic resistome by targeting keystone taxa Streptomyces" . | MICROBIOME 13 . 1 (2025) . |
| APA | Liao, Hanpeng , Wen, Chang , Huang, Dan , Liu, Chen , Gao, Tian , Du, Qiyao et al. Harnessing phage consortia to mitigate the soil antibiotic resistome by targeting keystone taxa Streptomyces . | MICROBIOME , 2025 , 13 (1) . |
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Because of the recent widespread usage of antibiotics,the acquisition and dissemination of antibiotic-resistance genes(ARGs)were prevalent in the majority of habitats.Generally,the biological wastewater treatment processes used in wastewater treatment plants have a limited efficiencies of antibiotics resistant bacteria(ARB)disinfection and ARGs degrada-tion and even promote the proliferation of ARGs.Problematically,ARB and ARGs in effluent pose potential risks if they are not further treated.Photocatalytic oxidation is considered a promising disinfection technology,where the photocatalytic process generates many free radicals that enhance the interaction between light and deoxyribonucleic acid(DNA)for ARB elimination and subsequent degradation of ARGs.This review aims to illustrate the progress of photocatalytic oxidation technology for removing antibiotics resistant(AR)from wastew-ater in recent years.We discuss the sources and transfer of ARGs in wastewater.The over-all removal efficiencies of ultraviolet radiation(UV)/chlorination,UV/ozone,UV/H2O2,and UV/sulfate-radical based system for ARB and ARGs,as well as the experimental parameters and removal mechanisms,are systematically discussed.The contribution of photocatalytic materials based on TiO2 and g-C3N4 to the inactivation of ARB and degradation of ARGs is highlighted,producing many free radicals to attack ARB and ARGs while effectively limiting the horizontal gene transfer(HGT)in wastewater.Finally,based on the reviewed studies,fu-ture research directions are proposed to realize specific photocatalytic oxidation technology applications and overcome current challenges.
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| GB/T 7714 | Zicong Guo , Xiang Tang , Wenjun Wang et al. The photo-based treatment technology simultaneously removes resistant bacteria and resistant genes from wastewater [J]. | 环境科学学报(英文版) , 2025 , 148 (2) : 243-262 . |
| MLA | Zicong Guo et al. "The photo-based treatment technology simultaneously removes resistant bacteria and resistant genes from wastewater" . | 环境科学学报(英文版) 148 . 2 (2025) : 243-262 . |
| APA | Zicong Guo , Xiang Tang , Wenjun Wang , Zhangxiong Luo , Yuxi Zeng , Nan Zhou et al. The photo-based treatment technology simultaneously removes resistant bacteria and resistant genes from wastewater . | 环境科学学报(英文版) , 2025 , 148 (2) , 243-262 . |
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The application of magnetic biochar in anaerobic digestion (AD) has gained increasing attention. However, the underlying mechanisms remain insufficiently understood. This study systematically investigated the effects of magnetic biochar on functional microbial communities involved in methanogenesis and elucidated its role in promoting direct interspecies electron transfer (DIET) within AD systems. The addition of 40 mg g(-1) TSadded of magnetic biochar significantly enhanced methane production by 42.21 %, reaching 223.08 mL g(-1) TS with highest organic matter degradation efficiency. Microbial community analysis showed that magnetic biochar significantly enriched microorganisms associated with hydrolysis, acidogenesis, and methanogenesis, as well as electroactive microorganisms' abundance such as Geobacter spp., Syntrophus spp., P. aestuarii, and M. harundinacea, providing direct evidence for the DIET process of AD with magnetic biochar. Furthermore, the abundance of key genes involved in the DIET, including pilA, Fpo, and the genes encoded outer-membrane c-type cytochromes, was respectively upregulated by 44.49 %, 22.04 %, and 37.6 % in the presence of magnetic biochar. These findings suggest that magnetic biochar enhances the production of conductive pili and cytochrome c, facilitating extracellular electron transfer between syntrophic microorganisms. This accelerated electron transfer promotes CO2 reduction to CH4, ultimately improving methane production efficiency in the AD system. Moreover, the enhancement of hydrogenotrophic methanogenesis was particularly pronounced with magnetic biochar, further contributing to the improved AD performance. This study provides novel mechanistic insights into biochar-mediated DIET, offering a theoretical basis for optimizing biochar applications in AD.
Keyword :
DIET DIET Electroactive microorganisms Electroactive microorganisms Metagenomics Metagenomics Methanogenesis Methanogenesis Microbial succession Microbial succession
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| GB/T 7714 | Zhang, Yanru , Ye, Yuhang , Fang, Minghui et al. Biogas production enhancement from anaerobic digestion with magnetic biochar: Insights into the functional microbes and DIET [J]. | JOURNAL OF ENVIRONMENTAL MANAGEMENT , 2025 , 381 . |
| MLA | Zhang, Yanru et al. "Biogas production enhancement from anaerobic digestion with magnetic biochar: Insights into the functional microbes and DIET" . | JOURNAL OF ENVIRONMENTAL MANAGEMENT 381 (2025) . |
| APA | Zhang, Yanru , Ye, Yuhang , Fang, Minghui , Xiang, Yinping , Chen, Jianfei , Tang, Xiang et al. Biogas production enhancement from anaerobic digestion with magnetic biochar: Insights into the functional microbes and DIET . | JOURNAL OF ENVIRONMENTAL MANAGEMENT , 2025 , 381 . |
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Understanding the extraordinary environmental adaptability of prokaryotes is crucial for manipulating microbial communities, as their adaptive mechanisms drive community dynamics, resilience and functional responses to interventions like bioremediation. Microbial adaptation to the environment is shaped not only by their intrinsic characteristics but also by interactions with other microorganisms. Among them, temperate phages, which reside alongside cellular microorganisms across diverse ecosystems, are emerging as key players in microbial adaptation. This review delves into the contribution of temperate phages to microbial adaptation across multiple levels. It begins with a survey of culture-dependent studies that reveal the complex mechanisms by which temperate phages facilitate adaptation at the individual and population levels. The review then explores how temperate phage-host symbioses interact with selection pressures in complex environments, assessing both the influence of these pressures on lysogeny at the community level and how prophages respond. Finally, building on established concepts and recent scientific advances, this review outlines the potential for harnessing temperate phages to help address major societal challenges. This synthesis underscores the importance of temperate phages and encourages further exploration in phage ecology.
Keyword :
auxiliary metabolic genes (AMGs) auxiliary metabolic genes (AMGs) microbial adaptation microbial adaptation prophage prophage temperate phage temperate phage
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| GB/T 7714 | Tang, Xiang , Liao, Han-Peng , Gao, Jiang-Tao et al. Omnipresent Allies: The Role of Temperate Phages in Microbial Adaptation Across Ecosystems [J]. | ENVIRONMENTAL MICROBIOLOGY , 2025 , 27 (11) . |
| MLA | Tang, Xiang et al. "Omnipresent Allies: The Role of Temperate Phages in Microbial Adaptation Across Ecosystems" . | ENVIRONMENTAL MICROBIOLOGY 27 . 11 (2025) . |
| APA | Tang, Xiang , Liao, Han-Peng , Gao, Jiang-Tao , Yang, Qiu-E , Rensing, Christopher , Zhou, Shun-Gui . Omnipresent Allies: The Role of Temperate Phages in Microbial Adaptation Across Ecosystems . | ENVIRONMENTAL MICROBIOLOGY , 2025 , 27 (11) . |
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Hyperthermophilic composting (HTC) is a promising strategy for the treatment of organic solid waste, leveraging extreme thermophilic conditions (up to 90 degrees C) driven by specialized microbial communities. While microbial community composition and succession have been previously described during HTC, the metabolic activity and adaptation of thermophilic microbiomes remain largely unexplored. In this study, we conducted time-series metagenomic and metatranscriptomic analyses on samples from a full-scale HTC system to characterize the composition, functional potential, and metabolic activity of thermophilic bacteria. A total of 227 non-redundant metagenome-assembled genomes (MAGs) were recovered, including 45 thermophilic MAGs (optimal growth temperatures > 45 degrees C). Metatranscriptomic profiling revealed that thermophilic taxa-such as Thermus thermophilus, Planifilum fulgidum, and Thermaerobacter spp.-were highly transcriptionally active and played vital roles in heat generation through the upregulation of energy production and carbohydrate metabolism pathways. Additionally, these thermophiles exhibited survival and adaptation strategies involving physiological changes (e.g., spore formation, enhanced motility, and genome streamlining) and the induction of thermal resistance mechanisms (e.g., DNA repair systems, heat-shock proteins, and synthesis of compatible solutes). Overall, this study provides novel insights into the diverse survival strategies of thermophilic microbiomes in HTC and suggests potential avenues for optimizing thermophilic biotreatment processes for solid waste management. IMPORTANCE Despite increasing interest in hyperthermophilic composting as a sustainable waste treatment strategy, the mechanisms by which microbial communities both tolerate and drive extreme thermal conditions remain unclear. This study fills a critical knowledge gap by identifying a small group of highly active thermophilic bacteria that dominate during peak composting temperatures and orchestrate endogenous heat production. Using genome-resolved multi-omics, we demonstrate that these thermophiles couple high metabolic output with specialized survival strategies-such as genome streamlining, thermotolerance systems, and adaptive motility systems. These findings advance our understanding of microbial function under extreme conditions and provide a framework for optimizing thermophilic microbiome performance in engineered ecosystems.
Keyword :
hyperthermophilic composting hyperthermophilic composting metabolic activities metabolic activities metagenomics metagenomics metatranscriptomics metatranscriptomics microbiome microbiome
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| GB/T 7714 | Liu, Chen , He, Yuqi , Zhang, Hongbo et al. Metabolic activity and survival strategies of thermophilic microbiomes during hyperthermophilic composting [J]. | MSYSTEMS , 2025 , 10 (11) . |
| MLA | Liu, Chen et al. "Metabolic activity and survival strategies of thermophilic microbiomes during hyperthermophilic composting" . | MSYSTEMS 10 . 11 (2025) . |
| APA | Liu, Chen , He, Yuqi , Zhang, Hongbo , Zhang, Dong , Ai, Chaofan , Tang, Xiang et al. Metabolic activity and survival strategies of thermophilic microbiomes during hyperthermophilic composting . | MSYSTEMS , 2025 , 10 (11) . |
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Antibiotic-resistant bacteria (ARB) and antibiotic resistance genes (ARGs) have gradually become a tough challenge in wastewater treatment, posing a serious threat to global health. Sulfate radical-based advanced oxidation processes (SR-AOPs) were regarded as an alternative to eliminate antibiotic resistance (AR). Our work provided a natural illite for activating PMS to inactivate ARB and degrade ARGs. 5.5-log e-blaTEM-1 and 3.1-loge-tetA were removed within 15 min, impeding the dissemination of AR. The generated center dot OH, SO4 center dot-, and 1O2 in the illte/PMS system completely inactivated ARB within 30 min (7.6-log), and no regeneration was observed within 72 h. Flow cytometry and electron microscopy visualized and further confirmed the cell inactivation. Transcriptomic analysis revealed the downregulation of key functional genes underlying the ARB inactivation. Furthermore, illite/PMS could adapt to various external environments and resist the interference of anions and organic substances. Finally, illite/PMS was applied to treat turtle farming wastewater and increased the abundance of beneficial bacteria and fungi, which was promising for wastewater purification. Collectively, our results suggested the feasibility of illite coupled with PMS for simultaneous ARB and ARGs removal in real water matrices.
Keyword :
antibiotic resistance genes antibiotic resistance genes antibiotic resistant-bacteria antibiotic resistant-bacteria Illite Illite PMS PMS turtle farming wastewater turtle farming wastewater
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| GB/T 7714 | Zhou, Xiangqin , Zhou, Ting , Xiong, Jiuqiang et al. Synergistic control of antibiotic resistance via natural illite-activated peroxymonosulfate: Efficiency and mechanism [J]. | JOURNAL OF HAZARDOUS MATERIALS , 2025 , 500 . |
| MLA | Zhou, Xiangqin et al. "Synergistic control of antibiotic resistance via natural illite-activated peroxymonosulfate: Efficiency and mechanism" . | JOURNAL OF HAZARDOUS MATERIALS 500 (2025) . |
| APA | Zhou, Xiangqin , Zhou, Ting , Xiong, Jiuqiang , Wang, Wenjun , Li, Yingbin , Li, Long et al. Synergistic control of antibiotic resistance via natural illite-activated peroxymonosulfate: Efficiency and mechanism . | JOURNAL OF HAZARDOUS MATERIALS , 2025 , 500 . |
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Atom-site catalysts, especially for graphitic carbon nitride-based catalysts, represents one of the most promising candidates in catalysis membrane for water decontamination. However, unravelling the intricate relationships between synthesis-structure-properties remains a great challenge. This study addresses the impacts of coordination environment and structure units of metal central sites based on Mantel test, correlation analysis, and evolution of metal central sites. An optimized unconventional oxygen doping cooperated with Co-N-Fe dual-sites (OCN Co/Fe) exhibits synergistic mechanism for efficient peroxymonosulfate activation, which benefits from a significant increase in charge density at the active sites and the regulation in the natural population of orbitals, leading to selective generation of SO4 center dot-. Building upon these findings, the OCN-Co/Fe/PVDF composite membrane demonstrates a 33 min-1 ciprofloxacin (CIP) rejection efficiency and maintains over 96% CIP removal efficiency (over 24 h) with an average permeance of 130.95 L m-2 h-1. This work offers a fundamental guide for elucidating the definitive origin of catalytic performance in advance oxidation process to facilitate the rational design of separation catalysis membrane with improved performance and enhanced stability. The relationships between synthesis-structure-properties are unraveled based on Mantel test, correlation analysis, and evolution of metal central sites. The as-synthesized oxygen doping cooperated with Co-N-Fe dual-sites exhibits high activity and selectivity for SO4 center dot- generation during PMS activation. Building upon these findings, a separation catalysis membrane loading OCN-Co/Fe catalysts within microreactors is constructed, which displays exceptional permeability and durability. image
Keyword :
catalysis membrane catalysis membrane coordination environment modulation coordination environment modulation dual-atom catalysts dual-atom catalysts graphitic carbon nitride graphitic carbon nitride peroxymonosulfate peroxymonosulfate
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| GB/T 7714 | Wang, Ziwei , Yi, Zhigang , Wong, Lok Wing et al. Oxygen Doping Cooperated with Co-N-Fe Dual-Catalytic Sites: Synergistic Mechanism for Catalytic Water Purification within Nanoconfined Membrane [J]. | ADVANCED MATERIALS , 2024 , 36 (30) . |
| MLA | Wang, Ziwei et al. "Oxygen Doping Cooperated with Co-N-Fe Dual-Catalytic Sites: Synergistic Mechanism for Catalytic Water Purification within Nanoconfined Membrane" . | ADVANCED MATERIALS 36 . 30 (2024) . |
| APA | Wang, Ziwei , Yi, Zhigang , Wong, Lok Wing , Tang, Xiang , Wang, Hou , Wang, Han et al. Oxygen Doping Cooperated with Co-N-Fe Dual-Catalytic Sites: Synergistic Mechanism for Catalytic Water Purification within Nanoconfined Membrane . | ADVANCED MATERIALS , 2024 , 36 (30) . |
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