Achieving high-efficient photocatalytic persulfate-activated degradation of tetracycline via carbon dots modified MIL-101(Fe)octahedrons

The synergistic reaction of photocatalysis and advanced oxidation is a valid strategy for the degradation of harmful antibiotic wastewater.Herein,carbon dots(CDs)modified MIL-101(Fe)octahedrons to form CDs/MIL-101(Fe)composite photocatalyst was synthesized for visible light-driven photocatalytic/persulfate(PS)-activated tetracycline(TC)degradation.The electron spin resonance(ESR)spectra,scavenging experiment and electrochemical analysis were carried out to reveal that the high visible light-driven photocatalytic degradation activity of TC over CDs/MIL-101(Fe)photocatalysts is not only ascribed to the production of free active radicals in the CDs/MIL-101(Fe)/PS system(·OH,·SO_(4-),^(1)O_(2),h^(+)and·O_(2)^(-))but also attributed to the consumption of electrons caused by the PS,which can suppress the recombination of photo-generated carriers as well as strong light scattering and electron trapping effects of CDs.Finally,the possible degradation pathways were proposed by analyzing intermediates via liquid chromatography-mass spectrometry technique.This research presents a rational design conception to construct a CDs/PS-based photocatalysis/advanced oxidation technology with high-efficient degradation activity for the remediation of organic antibiotic pollutant wastewater and for the improvement of carrier transport kinetics of photocatalysts.

Silicalite-1 zeolite encapsulated Fe nanocatalyst for Fenton-like degradation of methylene blue

Encapsulation of Fe nanoparticles in zeolite is a promising way to significantly improve the catalytic activity and stability of Fe-based catalysts during the degradation process of organic pollutants.Herein,Fe nanocatalysts were encapsulated into silicalite-1(S-1)zeolite by using a ligand-protected method(with dicyandiamide(DCD)as a organic ligand)under direct hydrothermal synthesis condition.High-resolution transmission electron microscopy(HRTEM)results confirmed the high dispersion of Fe nanocatalysts which were successfully encapsulated within the voids among the primary particles of the S-1 zeolite.The developed S-1 zeolite encapsulated Fe nanocatalyst(Fe@S-1)exhibited significantly improved catalytic activity and reusability in the catalytic degradation process of methylene blue(MB).Specifically,the developed Fe0.021@S-1 catalyst showed high catalytic degradation activity,giving a high MB degradation efficiency of 100%in 30 min,outperformed the conventional impregnated catalyst(Fe/S-1).Moreover,the Fe@S-1 catalyst afforded an outstanding stability,showing only ca.7.9%activity loss after five cycling tests,while the Fe/S-1 catalyst presented a significantly activity loss of 50.9%after only three cycles.Notably,the encapsulation strategy enabled a relatively lower Fe loading in the Fe@S-1 catalyst in comparison with that of the Fe/S-1 catalyst,i.e.,0.35%vs.0.81%(mass).Radical scavenging experiments along with electron spin resonance(ESR)measurements confirmed that the major role of
OH in the MB degradation process.Specifically,Fe@S-1 catalyst with high molar ratio of[Fe(DCD)]Cl3 is beneficial to form Fe complexes/nanoclusters in the voids(which has large pore size of 1–2 nm)among the primary particles of the zeolite,and thus improving the diffusion and accessibility of reactants to Fe active sites,and thus exhibiting a relatively higher degradation efficiency.This work demonstrates that zeolite-encapsulated Fe nanocatalysts present potential applications in the advanced oxidation of wastewater treatment.

金属有机框架MIL-101(Fe)用于增强光催化降解含油污水中的原油

利用溶剂热法合成了一种稳定的金属有机框架(MOF)MIL-101(Fe),并作为一种新型光催化剂提高了油田废水中原油的降解性能。通过对反应条件的优化,确定了以下最佳参数:暗反应时间为30 min,光反应时间为30 min,p H值为5.5,催化剂量为150 mg/L,反应温度为303.15 K。在这些反应条件下,去除率达到了94.73%。本研究是铁基MOFs在油田废水光催化降解中的应用。MIL-101(Fe)在温和的酸性条件下表现出良好的稳定性,并且可以有效地循环利用。这些发现为利用MIL-101(Fe)作为一种很有前途的工业应用材料,通过光催化降解从受油污染的水中去除原油提供了有价值的见解。

Fe-Mn/TiO_(2)的制备及其催化臭氧氧化双酚A的性能研究

采用浸渍法制备Fe-Mn/TiO_(2)双金属催化材料,以双酚A(BPA)为目标降解物,探究了Fe-Mn/TiO_(2)对其的降解效果及降解机制。结果表明,Fe-Mn/TiO_(2)催化臭氧氧化降解BPA的去除率相较于单独TiO_(2)处理提升了83.4%;Fe、Mn成功负载且催化剂孔洞较丰富;相较于TiO_(2),Fe-Mn/TiO_(2)中锐钛矿质量分数增加能产生更多的羟基自由基。同时,Fe、Mn在TiO_(2)表面能发生价态转化,可作为活性位点促进臭氧分解为·OH等活性物质,增强催化反应活性。

可降解Fe@Fe-Zn骨组织工程支架体外生物相容性研究

目的以多孔铁为基体,利用脉冲电沉积制备可降解多孔Fe@Fe-Zn复合材料骨组织工程支架,以期提高材料的降解速率和抗菌性能。方法通过调节脉冲频率,得到不同Zn含量的Fe-Zn合金层;使用电子探针、X射线衍射仪、扫描电镜来研究材料的元素含量、相组成和显微结构;通过压缩测试考察支架的力学性能;用体外浸泡来考察材料的降解性能;用浸提液培养分析材料对小鼠胚胎成骨细胞的黏附铺展和细胞活性的影响;用浸提液和直接培养来探究材料的抗大肠杆菌性能。结果随脉冲频率增加,合金中Zn含量减小;不同合金均为单一的α(Fe)相;电沉积组织致密,杂质含量低;Zn含量为7.5%(均以质量分数计)时,支架抗压屈服强度较多孔铁提升6%;复合材料的降解速率为0.44~0.48 mm/a,较多孔铁有显著改善;复合材料浸提液在稀释到25%(体积分数)时,表现出良好的细胞相容性,且随Zn含量增加,细胞活性增强;Zn含量为7.5%时,材料的抗菌性能最好。结论通过电沉积制备的Fe@Fe-Zn支架的腐蚀速率相较于多孔铁有明显提高。随合金层中Zn含量的增加,其细胞活性增强,抗菌性能提高。Fe@Fe-Zn有望发展为可广泛应用的可降解骨组织工程支架材料。

Synergetic Effects of UV/Fe^(3+) Combined with Electrocatalysis for p-Nitrophenol Degradation

Synergetic effects for p-nitrophenol degradation were observed in the combination of two-advanced oxidation processes, UV/Fe3+ and electrocatalysis. The enhancement of removal rate for p-nitrophenol and COD was around 123% and 278%, respectively. The possible contributions for the synergetic effects were the electrochemically regeneration of ferric ion and the role of the oxygen that formed on the anode.

NTA-Fe@PDA/H_(2)O_(2)氧化去除废水中盐酸土霉素

利用聚多巴胺(PDA)与氮川三乙酸(NTA)接枝并螯合Fe^(3+),形成以PDA为载体、NTA为Fe^(3+)螯合剂的芬顿催化剂NTA-Fe@PDA,采用NTA-Fe@PDA/H_(2)O_(2)芬顿氧化法去除废水中盐酸土霉素(OTC).材料表征结果发现,NTA-Fe@PDA属于典型的介孔结构,Fe元素与有机配体成功螯合,PDA的聚合效果良好.探讨了H_(2)O_(2)投加量、NTA-Fe@PDA投加量和初始pH值对OTC降解的影响.结果表明,在NTA-Fe@PDA浓度为200mg/L,H_(2)O_(2)浓度为5mmol/L,初始pH值为4.85的条件下,反应60min后,20mg/L OTC的降解率达到96.23%.自由基鉴定实验表明,·OH是OTC降解过程中的主要自由基.通过LC-MS分析结果推测了OTC降解的中间产物和可能的降解路径.NTA-Fe@PDA在反应体系中重复利用8次以后,OTC的降解率仍在86.80%以上.NTA-Fe@PDA/H_(2)O_(2)芬顿法为抗生素废水处理提供了一种新思路和技术参考.

Photochemically enhanced degradation of phenol using heterogeneous Fenton-type catalysts

The degradation of phenol was carried out using heterogeneous Fenton-type catalysts in the presence of H_2O_2 and UV. Catalysts were prepared by exchanging and immobilizing Fe 2+ in zeolite 13X, silica gel or Al_2O_3. The concentration of phenol solution was 100 mg/L. The amount of H_2O_2 added was the stoichiometric amount of H_2O_2 required for the total oxidation of phenol. Under the irradiation of medium pressure light (300 W) phenol was mineralized within 1 h in the presence of Fe 2+/zeolite 13X. The COD removal rate was enhanced in the presence of Fe 2+/zeolite 13X compared to that of Fe 2+/silica gel or Fe 2+/Al_2O_3. Analogous homogenous photo-Fenton reaction with equivalent Fe 2+ was also carried out to evaluate the catalysis efficiency of Fe 2+/zeolite 13X. Results showed that the COD removal rate was near to that of homogeneous Fenton, while heterogeneous Fe 2+/zeolite 13X catalyst could be recycled.

Degradation of Azo Dyes by Photocatalysis of Fe(Ⅲ)-oxalate Complexes/H_2O_2 in Aqueous Non-ionic Surfactant Triton X-100 Solution

Two azo dyes,C.I.Reactive Red 195(RR195)and C.I.Acid Black 234(AB234)were degraded by photocatalysis of Fe(Ⅲ)-oxalate complexes/H2O2 in aqueous non-ionic surfactant,Triton X-100(TX-100)solution.Some factors affecting the dye degradation such as TX-100 concentration,irradiation intensity,and sodium chloride were investigated.The interaction and competition between dye and TX-100 during the degradation were also examined using spectrophotometry and maximum bubble pressure method,respectively.The results indicated that TX-100 showed a significant reduction effect on degradation of two azo dyes,but which was largely confined to TX-100 concentration below the Critical Micellar Concentration(CMC).And the reduction was considerably decreased above the CMC,especially in the case of AB234.Moreover,the reducing effect of TX-100 on dye degradation almost did not vary with irradiation intensity.And the impact of sodium chloride on dye degradation was limited by the addition of TX-100.

Enhanced activation of peroxymonosulfate by Fe/N co-doped ordered mesoporous carbon with dual active sites for efficient removal of m-cresol

The novel Fe-N co-doped ordered mesoporous carbon with high catalytic activity in m-cresol removal was prepared by urea-assisted impregnation and simple pyrolysis method.During the preparation of the Fe-NC catalyst,the complexation of N elements in urea could anchor Fe,and the formation of C3N4during urea pyrolysis could also prevent migration and aggregation of Fe species,which jointly improve the dispersion and stability of Fe.The FeN4sites and highly dispersed Fe nanoparticles synergistically trigger the dual-site peroxymonosulfate (PMS) activation for highly efficient m-cresol degradation,while the ordered mesoporous structure of the catalyst could improve the mass transfer rate of the catalytic process,which together promote catalytic degradation of m-cresol by PMS activation.Reactive oxygen species (ROS) analytic experiments demonstrate that the system degrades m-cresol by free radical pathway mainly based on SO_(4)^(-)·and·OH,and partially based on·OH as the active components,and a possible PMS activation mechanism by 5Fe-50 for m-cresol degradation was proposed.This study can provide theoretical guidance for the preparation of efficient and stable catalysts for the degradation of organic pollutants by activated PMS.

Optimization of Conditions for the Photocatalytic Degradation of EDTA in Aqueous Solution with Fe-Doped Titanium Dioxide

The conditions for photocatalytic degradation of ethylenediaminetetraacetic acid (EDTA) in aqueous solution with Fe-doped titanium dioxide (TiO2) were optimized. The degradation efficiencies with Fe-doped TiO2 were better, compared with those obtained with bare TiO2 and Pt-doped TiO2. The effect of various experimental factors, such as photocatalytic dosage, temperature, solution pH and light intensity on the photocatalytic degradation of EDTA by Fe-doped TiO2 was investigated. The photocatalytic degradation treatment for the wastewater containing EDTA is simple, easy handling and low cost.

Mn促进Fe/C微电解反应速率及降解污染物机理

为了扩宽铁炭微电解工艺的适用范围及提高处理效率,以铸铁屑、椰壳活性炭为原料,添加Mn构建Fe/Mn/C三元微电解体系处理甲基橙(MO)模拟染料废水。利用SEM-EDS、FTIR及Raman光谱分析了Fe、Mn和活性炭表面形貌及元素组成,采用UV和三维荧光光谱(EEM)探究了有机物成分的变化,对比了Fe/Mn/C和Fe/C微电解体系对MO的降解效果,揭示了Fe/Mn/C三元微电解体系降解MO的反应机理和反应动力学。结果表明,反应后的Fe、Mn和炭填料表面存在铁氧化物、铁氢氧化物及锰氧化物,Fe/Mn/C三元微电解体系可断裂MO的氮氮双键,破坏苯环结构。MO的降解过程符合准一级反应动力学模型;Fe/Mn/C微电解体系对MO降解的反应速率常数由Fe/C微电解体系的5.7381×10^(-4)min^(-1)提高至9.3834×10^(-4)min^(-1),降解速率和降解效果显著优于Fe/C微电解体系。

Honeycomb-like biochar framework coupled with Fe_(3)O_(4)/FeS nanoparticles as efficient heterogeneous Fenton catalyst for phenol degradation

Achieving an efficient and stable heterogeneous Fenton reaction over a wide pH range is of great significance for wastewater treatment.Here,a pollen-derived biochar catalyst with a unique honeycomb-like structure,coupled with the dispersion of magnetic Fe_(3)O_(4)/FeS(Fe/S)nanoparticles,was synthesized by simple impregnation precursor,followed by pyrolysis.The prepared Fe/S-biochar catalyst demonstrated outstanding phenol degradation efficiency across a wide pH range,with 98%of which eliminated even under neutral conditions(pH 7.0).The high catalytic activity was due to the multilevel porous structure of pollenderived biochar provided enough active sites and allowed for better electron transfer,then increases oxidation ability to promote the reaction.Moreover,the acid microenvironment formed by SO_(4)^(2-)group from Fe/S composite extended the pH range for Fenton reaction,and S^(2-)facilitated the conversion of≡Fe^(3+)to≡Fe^(2+),resulting in remarkable degradation efficiency.Further,biochar can effectively promote cycling stability by limiting Fe leaching.This work may provide a general strategy for designing 3D framework biochar-based Fe/S catalysts with excellent performance for heterogeneous Fenton reactions.

Science Letters:Structure relationship of nitrochlorobenzene catalytic degradation process in water over palladium-iron bimetallic catalyst

Two isomers of nitrochlorobenzene (o-, and p-NCB) were treated by a Pd/Fe catalyst in aqueous solutions through catalytic amination and dechlorination. Nitrochlorobenzenes are rapidly converted to form chloroanilines (CAN) first through an amination process, and then rapidly dechlorinated to become aniline (AN) and Cl?, without the involvement of any other inter-mediate reaction products. The amination and dechlorination reaction are believed to take place predominantly on the surface site of the Pd/Fe catalysts. The dechlorination rate of the reductive degradation of the two isomers of nitrochlorobenzene (o-, and p-NCB) in the presence of Pd/Fe as a catalyst was measured experimentally. In all cases, the reaction rate constants were found to increase with the decrease in the Gibbs free energy (correlation with the activation energy) of NCBs formation; the activation energy of each dechlorination reaction was measured to be 95.83 and 77.05 kJ/mol, respectively for o- and p-NCB. The results demonstrated that p-NCBs were reduced more easily than o-NCBs.

Fe-Mn/AC催化H_(2)O_(2)降解染料废水

通过浸渍法制备的Fe-Mn/AC催化剂以活性炭作为载体,用于降解染料废水。利用SEM手段研究了Fe-Mn/AC催化剂的结构特征。阐述了染料废水的处理方法及制备方法。以甲基橙溶液模拟染料废水,研究了染料废水pH值、染料废水初始浓度、催化剂投加量、H_(2)O_(2)浓度对催化剂催化H_(2)O_(2)降解染料废水的影响。实验结果显示,pH值为3,催化剂投加量为0.2g,染料废水初始浓度为50mg/L,H_(2)O_(2)浓度为7.5mmol/L为最佳反应条件。在最优条件下,通过3h的吸附降解处理,染料废水的去除率达到98%。

多面体型Fe基金属有机框架材料(Fe-MOF)的调控制备及其性能

FeCl_(3)与邻苯二甲酸、对苯二甲酸等双齿配体在N,N-二甲基甲酰胺(DMF)溶剂热条件下配位聚合形成Fe基金属有机框架材料(FeMOF),以单齿配体苯甲酸作为调节剂,调节配位过程,通过配位竞争得到粒径较大的晶体,借助X射线衍射(XRD)、电镜扫描(SEM)对产物进行表征,以亚甲基蓝为有机污染物,对所得产物的吸附、催化降解性能进行评价。结果表明,随着反应时间的延长,FeMOF晶型由八面体转成二十面体,苯甲酸作调节剂使锥体晶型的尖角变得圆滑;n(单齿配体):n(双齿配体)=5:1、120℃条件下反应36h制得的FeMOF具有较好的吸附和催化性能。

Fe/TiO_(2-x)可见光活化过硫酸盐降解双酚A的作用机制

以TiO_(2)和FeCl_(3)为原料,通过水热-煅烧的方法成功制备了具有高可见光催化活性的Fe/TiO_(2-x)催化剂并将其应用于催化活化过硫酸盐降解BPA的研究中.结果表明,研究体系具有优秀的催化氧化能力,BPA(50mg/L)的降解率在40min内达到100%,矿化度达到68.92%,研究同时对复合材料中有无Ti^(3+)的自掺杂以及催化剂的投加量、PS浓度对体系降解有机物效能的影响进行了探究.该体系可通过自生光电子还原Fe^(3+)实现三价铁和二价铁的高效循环.硫酸根自由基(SO_(4)^(-)•)和羟基自由基(•OH)为体系中主要的活性氧化物质,其中•OH贡献率超过66.2%.研究结果同时表明,碱性环境以及体系中的CO_(3)^(2-)对体系降解效能具有抑制作用.

生物可降解梯度多孔Fe-3Ag/HA复合材料的制备与性能研究

采用粉末冶金技术制备梯度多孔Fe-3Ag/HA复合材料,研究了造孔剂分布、烧结温度、HA含量对梯度多孔Fe-3Ag/HA复合材料的孔隙度和力学性能的影响。观察了梯度多孔Fe-3Ag/HA复合材料的显微组织及腐蚀后的微观形貌,测量了梯度多孔Fe-3Ag/HA复合材料的物相组成和耐腐蚀性能。结果表明,随着造孔剂和HA含量增加,烧结产物的孔隙度增加,抗压强度减少。提高造孔剂含量,梯度多孔Fe-3Ag/HA复合材料的耐腐蚀性能明显降低;提高HA含量,该复合物的耐腐蚀性能比梯度多孔Fe-3Ag略有增加,但是其腐蚀速率明显高于梯度多孔纯Fe试样。在模拟人工体液中浸泡3天后,梯度多孔Fe-3Ag/HA复合材料比梯度多孔Fe-3Ag合金表面沉积了更多的HA,这表明HA相有诱导模拟人工体液中Ca和P离子沉积的能力,与Fe基合金相比该复合材料具有更好的生物相容性。

MIL-101(Fe)的合成条件优化及RhB催化降解

通过溶剂热法合成了拉瓦锡材料研究所骨架材料(Materials of Institute Lavoisier,MILs)中的MIL-101(Fe)材料,将其应用于活化过二硫酸盐(PDS)降解罗丹明B(RhB),并优化了反应物配比、合成温度、合成时间等制备条件,优化后的MIL-101(Fe)催化活性得到有效提升。同时探究了MIL-101(Fe)/PDS体系催化降解RhB的最佳反应条件,在RhB初始质量浓度为10 mg/L、PDS投加量为6 mmol/L、催化剂投加量0.2 g/L、初始pH=3、t=25℃的条件下,t<20 min,RhB去除率即可达到100%。

新型MIL-101(Fe)/BiOBr S型异质催化剂用于高效光催化降解抗生素和还原六价铬:光催化性能分析和光催化机理研究

水污染对生态环境和人类健康造成了巨大危害,特别是水体中抗生素和重金属具有毒性且难生物降解,已经引起科研工作者的广泛关注.传统的水处理技术难以有效地消除这些污染物.近年来,人们致力于开发绿色、低碳且高效的光催化技术用于解决环境污染问题,该技术实现大规模应用的核心在于开发出经济、高效的光催化剂.由于单一半导体光催化材料(如BiOBr)存在一些缺陷(如有限的催化活性位点和光生电子-空穴快速复合等),因此,构建具有可见光响应、高暴露活性位点和强氧化还原能力的异质结特别是新兴的梯(S)型异质结是去除这些污染物的有效策略之一.MIL-101(Fe)是一种新型的可见光驱动的金属-有机配体框架材料,具有强还原活性、高比表面积和较好的可见光吸收能力,因此,将氧化型的Bi OBr与还原型的MIL-101(Fe)进行合理设计,构筑S型异质结,有望开发出高效的催化材料.本文采用溶剂热法成功制备了一种新型的MOF基S型异质结MIL-101(Fe)/BiOBr,用于可见光照射下光催化还原六价铬(Cr(Ⅵ))和降解抗生素恩诺沙星.结果表明,在单一污染物体系中,MIL-101(Fe)/BiOBr可有效还原99.4%的Cr(Ⅵ)和氧化分解84.4%的恩诺沙星.值得注意的是,在Cr(Ⅵ)和恩诺沙星共存的条件下,MIL-101(Fe)/BiOBr对(Cr(Ⅵ))和恩诺沙星的去除效率明显提升,这主要是由于S型催化剂、Cr(Ⅵ)和恩诺沙星之间具有协同效应.MIL-101(Fe)/BiOBr催化剂活性增强的主要因素如下:(1)MIL-101(Fe)提供了大量的活性位点,改善了催化材料的光吸收能力.(2)S型载流子分离路径不但促进了电子和空穴的高效分离,而且增强了体系的氧化还原能力.此外,采用自由基捕获实验、电子自旋共振波谱仪、液相色谱-质谱联用技术以及毒性分析软件,系统分析了光催化反应机理、抗生素分解过程和中间产物的生物毒性.综上,本文提供一种简单有效的策略来构筑高活性的MOF/无机半导体S型异质结材料用于高效净化水体环境.