铁铜催化剂非均相Fenton降解苯酚及机制研究

通过浸渍法制备了负载于活性炭(AC)上的金属催化剂Fe/AC、Cu/AC和Fe-Cu/AC,并通过X射线衍射(XRD)、物理吸附仪及X射线光电子能谱(XPS)对其进行了表征.研究了非均相Fenton反应催化H2O2降解苯酚废水的工艺参数,并通过中间产物分析和电子自旋共振谱(ESR)探讨了过程反应机制.实验表明,Cu/AC催化剂中铜主要以CuO形式存在,Fe/AC中铁以多价态形式存在,以无定形形态分散于活性炭中.Fe/AC、Cu/AC和Fe-Cu/AC催化过氧化氢降解苯酚60 min内降解率分别达到96.7%、77.5%和99%;Cu/AC和Fe-Cu/AC催化剂中活性组分铜和铁有一定溶出,而Fe/AC中活性组分铁溶出很少,苯酚降解主要是以非均相催化为主,同时在三轮循环实验后的苯酚降解率仍然高达93%以上,显示了良好的催化稳定性.在优化条件pH=3、T=303 K及初始H2O2为4.38 mmol.L-1下,Fe/AC催化过氧化氢对苯酚和TOC去除率分别达到97%和53%,没有催化剂时苯酚几乎不降解.ESR结果表明Fe/AC催化过氧化氢产生了羟基自由基,证明苯酚降解是以羟基自由基氧化为主;通过高效液相色谱(HPLC)检测苯酚降解中间产物主要有邻苯二酚、对苯二酚和对苯醌,推测苯酚降解途径主要为邻位和对位的羟基取代反应.     

Metal ion catalyzed oxidation of SO2 in the presence of trace H2O2 in aqueous solution under environmental reaction conditions

Aqueous phase oxidation of SO₂ or S(IV) by H₂O₂-metal ions at a H₂O₂ concentration much lower than S(IV), was studied using a continuously flowing stirred reactor. Of the metal ions, Fe²⁺ showed the highest catalytic activity, i.e. the oxidation of S(IV) continued after most of the H₂O₂ was consumed. The dependence of the rate on the concentration of S(IV), H₂O₂, Fe²⁺ or H⁺ and temperature was determined. The following rate expression and low apparent activation energy of 40.7 kJ mole⁻¹ were evaluated,−d[S(IV)]/dt=620[S(IV)]²[Fe²⁺]^0.5(molel⁻¹S⁻¹). The significance of this reaction as the sulfate formation in atmospheric water droplets is discussed and a comparison of the rate with others using H₂O₂, O₃ and dissolved O₂ catalyzed by metal ions is made.     

Heterogeneous Fenton-like degradation of 4-chlorophenol using iron/ordered mesoporous carbon catalyst

Ordered mesoporous carbon supported iron catalysts(Fe/OMC) were prepared by the incipient wetness impregnation method and investigated in Fenton-like degradation of 4-chlorophenol(4CP) in this work. XRD and TEM characterization showed that the iron oxides were well dispersed on the OMC support and grew bigger with the increasing calcination temperature. The catalyst prepared with a lower calcination temperature showed higher decomposition efficiency towards 4CP and H2O2, but more metals were leached. The effect of different operational parameters such as initial pH, H2O2 dosage, and reaction temperature on the catalytic activity was evaluated. The results showed that 96.1% of 4CP and 47.4% of TOC was removed after 270 min at 30°C, initial pH of 3 and 6.6 mmol/L H2O2. 88% of 4CP removal efficiency was retained after three successive runs, indicating Fe/OMC a stable catalyst for Fenton reaction. 4CP was degraded predominately by the attack of hydroxyl radical formed on the catalyst surface and in the bulk solution due to iron leaching. Based on the degradation intermediates detected by high performance liquid chromatography, possible oxidation pathways were proposed during the 4CP degradation.     

纳米Fe/Co合金类Fenton降解盐酸四环素及影响因素

为研究纳米Fe/Co合金对含TCs（盐酸四环素）废水的类Fenton催化性能,以及催化降解体系pH、H₂O₂投加量和活性成分浸出等因素对催化性能的影响.采用液相还原法制备纳米Fe/Co合金,并通过对比试验探究其类Fenton催化性能,Fe、Co的浸出量及其表面积结构变化与活性之间的关系.添加纳米Fe/Co合金的条件下,采用单因素分析方法研究体系pH、H₂O₂投加量和初始TCs浓度分别对TCs去除率的影响.结果表明:①在纳米Fe/Co合金制备过程中,添加PVP（聚乙烯吡咯烷酮）不仅能有效防止纳米Fe/Co合金发生团聚,且促进纳米Fe/Co合金比表面积增大（BET为113.8 m2/g）.②纳米Fe/Co合金具有拓宽催化体系pH使用范围的优势;在pH为3.0~9.0范围内,纳米Fe/Co合金对30 mg/L TCs的去除率（87.2%~91.7%）远大于FeCl₂（0~30.7%）和纳米Fe的去除率（0~28.2%）;H₂O₂投加量超过150 mmol/L后,TCs的去除率达到最佳（86.2%）.③纳米Fe/Co合金催化体系中（pH为3.0~11.0）,活性成分Fe、Co浸出量分别为0.20~0.35和0.20~1.00 mg/L,均满足我国GB 3838—2002《地表水环境质量标准》,长期使用也不会造成浸出成分（Fe、Co）在环境中大量累积,对生态环境等可能造成的潜在风险大大降低.④纳米Fe/Co合金具有再利用性,催化利用4次后,对TCs的去除效果仍达50.0%以上.研究显示,纳米Fe/Co合金对去除TCs具有较高催化性能和再利用性,利于拓宽催化体系pH使用范围,具有稳定活性成分Fe、Co浓度的优势.      

活性炭催化过氧化氢去除荧光增白剂

研究了活性炭(activated carbon,AC)吸附、改性活性炭(activated carbon modified,ACM)吸附、过氧化氢(H2O2)氧化、AC催化H2O2等方法对水体中荧光增白剂VBL的处理效果,并通过自由基俘获剂叔丁醇、催化过程气体分析等探讨了AC催化H2O2分解VBL的机制.结果表明,经硝酸铁[Fe(NO3)3]改性过的ACM对VBL的吸附去除率高于未改性的AC.活性炭催化H2O2对VBL的去除效果明显,但未改性AC催化去除率高于ACM.60 min时,AC催化氧化去除率即可达到95%以上,而ACM仅为58%.叔丁醇的加入降低了AC和ACM催化氧化对VBL的去除率,表明AC催化H2O2氧化能促进H2O2形成羟基自由基(·OH)和原子氧参与反应.AC催化H2O2分解及释放气体分析表明,AC能催化H2O2形成氧气并放热,且ACM明显快于AC.结合催化H2O2去除VBL效率的结果分析,ACM催化反应时活性中间物(自由基和原子氧等)产生速率快于AC,活性中间物自身消耗形成氧气,而不是用于分解VBL.催化反应中活性中间产物的形成速率与反应物供给速率的不匹配可能是导致ACM催化效果弱于AC的重要原因.     

A kinetic model of Ti（IV）-catalyzed H2O2/O3 process in aqueous solution

A kinetic model for the Ti(IV)-catalyzed H₂O₂/O₃ process was established, and the experimental results demonstrated that the model could well describe this ozone-based oxidative system mathematically and chemically.     

Catalytic performance of Fe3O4-CoO/Al2O3 catalyst in ozonation of 2-(2,4-dichlorophenoxy)propionic acid, nitrobenzene and oxalic acid in water

Fe3O4-CoO/Al2O3 catalyst was prepared by incipient wetness impregnation using Fe(NO3) 3·9H2O and Co(NO3) 2·6H2O as the precursors,and its catalytic performance was investigated in ozonation of 2-(2,4-dichlorophenoxy) propionic acid(2,4-DP) ,nitrobenzene and oxalic acid.The experimental results indicated that Fe3O4-CoO/Al2O3 catalyst enabled an interesting improvement of ozonation eciency during the degradation of each organic pollutant,and the Fe3O4-CoO/Al2O3 catalytic ozonation system followed a radical-type mechanism.The kinetics of ozonation alone and Fe3O4-CoO/Al2O3 catalytic ozonation of three organic pollutants in aqueous solution were discussed under the mere consideration of direct ozone reaction and OH radical reaction to well investigate its performance.In the catalytic ozonation of 2,4-DP,the apparent reaction rate constants(k) were determined to be 1.456×10-2 min-1 for ozonation alone and 4.740×10-2 min-1 for O3/Fe3O4-CoO/Al2O3.And O3/Fe3O4-CoO/Al2O3 had a larger Rct(6.614×10-9) calculated by the relative method than O3 did(1.800×10-9) ,showing O3/Fe3O4-CoO/Al2O3 generated more hydroxyl radical.Similar results were also obtained in the catalytic ozonation of nitrobenzene and oxalic acid.The above results demonstrated that the catalytic performance of Fe3O4-CoO/Al2O3 in ozonation of studied organic substance was universal to a certain degree.     

Fe/Zn-TMS体系吸收去除催化裂化干气中H2S的性能

本研究采用FeCl3·6H2O、ZnCl2和环丁砜(TMS)复配形成的Fe/Zn-TMS体系脱除催化裂化(FCC)干气中的H2S,并用30%H2O2氧化再生Fe/Zn-TMS体系.同时,研究了各活性成分比例、吸收液体积浓度、吸收液pH值等对脱硫效率的影响,以及H2O2用量、吸收富液pH值对Fe2+氧化率的影响.结果表明,n(FeCl3·6H2O)∶n(ZnCl2)∶n(TMS)为0.45∶0.55∶1,吸收液pH为0.75,体积浓度(W)为50%的条件下能长时间高效脱硫,最高脱硫率达99.9%;在n(Fe2+)∶n(H2O2)为2∶1,吸收富液pH为0.65的条件下,Fe2+氧化率达96.7%.体系可循环使用3次,且能耗低、操作简单.     

Kinetics of microwave-enhanced oxidation of phenol by hydrogen peroxide

Aqueous solutions of phenol were oxidized by hydrogen peroxide assisted by microwave (MW) irradiation. A simple kinetic model for the overall degradation of phenol in the presence of excess H₂O₂ is proposed in which the degradation rate of phenol is expressed as a linear function of the concentrations of phenol and H₂O₂. A detailed parametric study showed that the degradation rate of phenol increased with increasing [H₂O₂] until saturation was observed. Phenol degradation followed apparent zero-order kinetics under MW radiation or H₂O₂ oxidation. However, after 90 min of irradiation, the observed kinetics shifted to pseudo first order. The overall reaction rates were significantly enhanced in the combined MW/H₂O₂ system, mainly because microwave could accelerate H₂O₂ to generate hydroxyl radical (·OH) and other reactive oxygen intermediates. The observed synergetic effects of the MW/H₂O₂ process resulted in an increased in the net reaction rate by a factor of 5.75. When hydrogen peroxide is present in a large stoichiometric excess, the time required to achieve complete mineralization is reduced significantly.     

纳米Fe/Co催化降解土霉素效果及影响因素研究

为探究液相还原法制备的纳米Fe/Co催化剂的类芬顿催化效果,以单因素分析法研究了pH、OTC（土霉素）初始质量浓度、H₂O₂摩尔浓度和催化剂用量对纳米Fe/Co催化剂催化性能的影响,并通过SEM（扫描电子显微镜）和BET（比表面积测试仪）对纳米Fe/Co催化剂进行表征,进一步研究了纳米Fe/Co催化剂对OTC模拟废水的催化降解效果.结果表明:①纳米Fe/Co催化剂可以有效地改善催化体系的pH使用范围,在pH为3.0~11.0范围内,纳米Fe/Co催化剂对浓度为100 mg/L OTC的去除率（94.0%）高于纳米Fe催化剂（85.0%）;低浓度OTC有利于提高污染物的去除率,而高浓度的OTC有利于提高反应速率;H₂O₂摩尔浓度为200 mmol/L时,纳米Fe/Co催化剂对OTC的去除率最高（93.8%）;纳米Fe/Co催化剂用量为6 g/L时,其对OTC的去除率最高（92.8%）.②纳米Fe/Co催化剂粒径为20~30 nm,比表面积较高,为121.3 m2/g.③纳米Fe/Co催化剂在重复利用13次后OTC去除率仍在50.0%以上,其重复利用性能良好.研究显示,纳米Fe/Co催化剂对OTC废水具有较好的催化性能、重复利用性能以及较宽的pH使用范围,可为含抗生素废水处理提供理论支撑.      

改性活性碳纤维电芬顿降解苯酚废水性能研究

采用微波改性、硝酸改性、磷酸改性及氨水改性等方法改性活性碳纤维(ACF-0),依次标记为ACF-1、ACF-2、ACF-3和ACF-4.以改性前后的活性碳纤维为阴极,电芬顿催化处理苯酚模拟废水,考察不同的改性方法对H2O2生成量、COD去除率、苯酚去除率及其中间产物的影响.结果表明,微波改性活性碳纤维的吸附性能及电催化活性最优,相比未改性活性碳纤维,经微波或酸碱改性后的活性碳纤维反应体系中,H2O2生成量均有所增加.苯酚在各电芬顿催化体系中的去除率大小依次是:ACF-1>ACF-3>ACF-4>ACF-2>ACF-0;COD去除率大小依次是:ACF-1>ACF-4>ACF-3>ACF-2>ACF-0,说明微波及酸碱改性有利于提高活性碳纤维的催化性能.此外,苯酚降解中间产物的生成也会受到改性方法的影响.     

Catalytic oxidation effect of MnSO4 on As(III) by air in alkaline solution

The catalytic oxidation effect of MnSO₄ on As(III) by air in an alkaline solution was investigated. According to the X-ray diffraction (XRD), scanning electron microscope-energy dispersive spectrometer (SEM-EDS) and X-ray photoelectron spectroscopy (XPS) analysis results of the product, it was shown that the introduction of MnSO₄ in the form of solution would generate Na_0.55Mn₂O₄·1.5H₂O with strong catalytic oxidation ability in the aerobic alkaline solution, whereas the catalytic effect of the other product MnOOH is not satisfactory. Under the optimal reaction conditions of temperature 90°C, As/Mn molar ratio 12.74:1, air flow rate 1.0 L/min, and stirring speed 300 r/min, As(III) can be completely oxidized after 2 hr reaction. The excellent catalytic oxidation ability of MnSO₄ on As(III) was mainly attributed to the indirect oxidation of As(III) by the product Na_0.55Mn₂O₄·1.5H₂O. This study shows a convenient and efficient process for the oxidation of As(III) in alkali solutions, which has potential application value for the pre-oxidation of arsenic-containing solution or the detoxification of As(III).     

One-step preparation of a novel graphitic biochar/Cu0/Fe3O4 composite using CO2-ambiance pyrolysis to activate peroxydisulfate for dye degradation

Herein,a one-step co-pyrolysis protocol was adopted for the first time to prepare a novel pyrogenic carbon-Cu⁰/Fe₃O₄ heteroatoms (FCBC) in CO₂ ambiance to discern the roles of each component in PDS activation.During co-pyrolysis,CO₂ catalyzed formation of reducing gases by biomass which facilitated reductive transformation of Fe³⁺ and Cu²⁺ to Cu⁰ and Fe₃O₄,respectively.According to the a...     

阴极原位产H2O2强化光电催化降解水中EDTA的研究

本研究构建了以活性碳纤维(Activated Carbon Fiber,ACF)为阴极,TiO_2/Ti与Ru O_2/Ti为双阳极的光电催化体系.该体系中,Ru O_2/Ti电阳极和TiO_2/Ti光阳极均有氧化作用,可同时氧化降解污染物;且电阳极具有较强析氧作用,能产生大量O_2;ACF阴极具有还原作用,可将体系中产生的O_2原位还原为H_2O_2;H_2O_2在紫外光下产生·OH,进而强化光电催化与电催化氧化过程,实现对水中乙二胺四乙酸二钠(EDTA)的高效去除.本论文详细考察了电流密度、pH、曝气等因素对EDTA降解效果的影响.结果表明,在EDTA初始浓度为300 mg·L~(-1)、溶液初始pH=4.84、电流密度为12 m A·cm~(-2)和光电流密度为0.012 m A·cm~(-2)的条件下,反应90 min后,EDTA降解率高于90%.该催化体系实现了EDTA的高效降解.     

膜生物反应器处理甲苯性能及机制

采用膜生物反应器处理甲苯有机废气,研究了进气浓度、停留时间、循环液喷淋密度和pH值对甲苯去除率的影响.膜生物反应器能高效净化挥发性有机废气,甲苯去除率可达99%.适宜运行条件为:pH值为7.2、停留时间为6.4 s、循环液喷淋密度为2.5 m3.(m2.h)-1.采用GC-MS分析出口气样,研究结果表明乙醛酸(C2H2O3)和乙烯基甲酸(C3H4O2)为甲苯生物降解的中间产物.膜生物反应器处理甲苯机制为甲苯气体通过中空纤维膜传质到生物膜,被生物降解为乙醛酸和乙烯基甲酸,然后继续好氧降解为最终产物二氧化碳和水.     

氮掺杂生物炭催化臭氧对于布洛芬的降解特性与机制

系统研究了新型氮掺杂生物炭材料(N-C)催化臭氧对于水中布洛芬(IBP)的氧化降解效能及机制,并深入探究了初始pH、臭氧投加量、催化剂投加量、不同阴离子和背景水质条件对IBP降解效率的影响.结果 表明,相较于一些常见的碳基催化剂(g-C3N4、生物炭、颗粒活性炭)及金属催化剂(MnO2、Fe3O4),N-C催化臭氧体系...     

TiO2光催化联合技术降解苯酚机制及动力学

主要研究了TiO2光催化体系结合H2O2或外加电催化(EC)体系对苯酚催化降解效率的影响,评价比较TiO2/UV、H2O2/UV、TiO2/UV/H2O2、TiO2/UV/EC体系下苯酚降解机制及动力学.结果表明,TiO2/UV/H2O2和TiO2/UV/EC体系下苯酚降解效率明显高于TiO2/UV体系,当苯酚溶液pH值为6,TiO2质量浓度0.2 g·L-1,紫外光照2 h,光催化降解效果达到86%,当电流密度为12 mA·cm-2,则苯酚可达到100%去除.比较了不同催化体系下的能量利用率,苯酚降解15 min,TiO2/UV/EC体系能量利用率最大为0.030 6 g·(kW·h)-1,其能量消耗为0.0640 kW·h-1,说明采用TiO2/UV/EC体系能更多地利用能量降解苯酚.通过不同催化体系下中间产物分析,建立苯酚及其中间产物对苯二酚、邻苯二酚和苯醌的拟一级降解动力学模型,通过模型验证各催化体系下苯酚的降解历程,同时也说明了TiO2/UV/EC体系有利于苯酚及其中间产物的降解.     

O3/H2O2去除水中硝基苯效果与机理

以硝基苯为目标反应物,对O₃/H₂O₂体系氧化去除水中硝基苯的效果和机理进行了研究,考察了pH值、H₂O₂剂量、自由基抑制剂或促进剂对硝基苯的去除效果的影响.研究发现,在pH≤7时,H₂O₂促进臭氧化去除硝基苯的效果较为明显,当H₂O₂投加量从1.0 mg/L增加到4.0 mg/L时,在氧化5 min内,硝基苯     

Degradation kinetics and mechanism of trace nitrobenzene by granular activated carbon enhanced microwave/hydrogen peroxide system

The kinetics of the degradation of trace nitrobenzene (NB) by a granular activated carbon (GAC) enhanced microwave (MW)/hydrogen peroxide (H₂O₂) system was studied. Effects of pH, NB initial concentration and tert-butyl alcohol on the removal efficiency were examined. It was found that the reaction rate fits well to first-order reaction kinetics in the MW/GAC/H₂O₂ process. Moreover, GAC greatly enhanced the degradation rate of NB in water. Under a given condition (MW power 300 W, H₂O₂ dosage 10 mg/L, pH 6.85 and temperature (60±5)℃), the degradation rate of NB was 0.05214 min^-1 when 4 g/L GAC was added. In general, alkaline pH was better for NB degradation; however, the optimum pH was 8.0 in the tested pH value range of 4.0-12.0. At H₂O₂ dosage of 10 mg/L and GAC dosage of 4 g/L, the removal of NB was decreased with increasing initial concentrations of NB, indicating that a low initial concentration was beneficial for the degradation of NB. These results indicated that the MW/GAC/H₂O₂ process was effective for trace NB degradation in water. Gas chromatography-mass spectrometry analysis indicated that a hydroxyl radical addition reaction and dehydrogenation reaction enhanced NB degradation.     

氮掺杂二氧化钛复合催化膜降解甲苯气体研究

采用溶胶-凝胶法以聚丙烯(PP)中空纤维膜为载体制备了N-Ti O2/PP复合催化膜,并考察了其催化降解甲苯有机废气的性能.结果发现,紫外光催化的甲苯降解率可达84%,去除负荷为89.8 g·m-3·h~(-1),自然光催化的甲苯降解率可达63.9%,去除负荷为69.25 g·m-3·h~(-1).同时,采用紫外-可见光谱(UV-Vis)、X-射线光电子能谱(XPS)和傅里叶变换红外光谱(FT-IR)表征了N-Ti O2/PP复合催化膜,并采用GC-MS分析甲苯降解过程的中间产物并推测甲苯反应过程机理.采用GC-MS分析出口气样的研究结果表明,苯(C6H6)、苯甲醛(C7H6O)、苯乙酸(C8H8O2)、丙烯醛(C3H4O)、甲酸甲酯(C2H4O2)为甲苯光催化降解的中间产物.N-Ti O2/PP复合催化膜降解甲苯的机制为甲苯气体通过中空纤维膜传质到N-Ti O2/PP复合催化膜,光催化产生羟基自由基,甲苯气体被羟基自由基氧化成中间产物,并继续降解为最终产物二氧化碳和水.