磷钨酸光催化六氟苯脱氟的研究

选择六氟苯作为目标化合物,利用266 nm脉冲激光照射磷钨酸与六氟苯的混合溶液证实了光催化转化六氟苯的可行性.结果表明,氟离子生成率与光照时间、pH值、磷钨酸初始投加量和添加物的量有关.氟离子生成率随激光脉冲次数的增加而升高.在溶液pH=1.0的条件下,氟离子生成率最高.2.0×10^-4mol/L的六氟苯与5.0×10^-6mol/L的磷钨酸的混合溶液在接受脉冲激光后,氟离子生成率可达208.1%.外加的氧化剂O₂、KMnO₄、K₂S₂O₈可以有效氧化还原态的磷钨酸,实现整个光催化循环.溶液中存在的醇类及芳香族有机化合物不利于磷钨酸光催化转化六氟苯.     

VUV/HPW/BMMs体系对全氟辛酸（PFOA）的脱氟研究

采用真空紫外灯(VUV)和双模型介孔材料(BMMs)负载磷钨酸(HPW)催化剂构建光催化体系,探究该体系对水中全氟辛酸(PFOA)的脱氟效果.研究了PFOA初始浓度、HPW/BMMs投加量、初始p H值对体系脱氟的影响,并采用响应曲面法(Response Surface Method,RSM)分析了最佳边界反应条件.结果表明,体系对PFOA具有明显的脱氟效果:脱氟效率随PFOA初始浓度的增大而减小;催化剂投加量为0.2 g·L~(-1),脱氟效率最高达50.2%;体系p H为3~4时,体系脱氟效果显著.基于Box-Behnken响应曲面法,各影响因子对脱氟效率的显著性排序为:p HPFOA初始浓度HPW/BMMs投加量.p H值与HPW/BMMs投加量及初始PFOA浓度交互作用显著,模型回归性良好,最佳运行条件为:p H=3.82,HPW/BMMs投加量为0.3 g·L~(-1),PFOA初始浓度为20 mg·L~(-1),反应4 h的脱氟率达到52.6%,与预测值相比偏差为1.2%.本研究为高效降解全氟化合物提供了新思路.     

电化学氧化PFOA阳极材料筛选及其机制研究

全氟辛酸(PFOA)具有环境持久性及内分泌干扰性,传统的生物降解及高级氧化法对PFOA的去除效果微弱.本研究采用电化学氧化法降解PFOA,选取BDD(掺硼金刚石电极)、Pt、Ti、Ti/RuO2、Ti/RuO2-IrO2、Ti/In2O3、Ti/SnO2-Sb2O5-IrO2、Ti/SnO2-Sb2O5-RhO2、Ti/SnO2-Sb2O5、Ti/SnO2-Sb2O5-CeO2和Ti/SnO2-Sb2O5-Bi2O3这11种阳极材料为备选电极.采用线性扫描伏安法测试析氧电位(OEP),评价11种电极对PFOA的降解效果和脱氟效果,并采用超声-电化学协同方法间接证明PFOA分子在电极表面的直接电子转移是降解反应的第一步.Ti/SnO2-Sb2O5-Bi2O3、Ti/SnO2-Sb2O5-CeO2、Ti/SnO2-Sb2O5和BDD对PFOA有较好的电氧化效果,降解率分别是89.8%、89.8%、93.3%和98.0%.Pt、Ti/SnO2-Sb2O5-RhO2、Ti/SnO2-Sb2O5-IrO2和Ti/In2O3对PFOA的电氧化效果微弱,降解率分别是2.1%、2.3%、12.5%和3.1%.而Ti、Ti/RuO2和Ti/RuO2-IrO2对PFOA没有电氧化能力.PFOA分子经过电极表面的直接电化学氧化发生脱羧反应,后经过逐步脱掉CF2单元的循环生成短链的全氟羧酸类化合物C6F13COO-、C5F11COO-、C4F9COO-和C3F7COO-.     

粒径对水合氧化镧除氟效果的影响

针对La2O3·nH2O的高效除氟作用,确定了La2O3·nH2O除氟的最佳pH,在此基础上研究了La2O3·nH2O的粒径对其除氟容量以及除氟动力学的影响,并与活性氧化铝除氟效果进行了对比.结果表明:La2O3·nH2O除氟的最佳pH为5.5～6.5;La2O3·nH2O对氟的吸附基本符合Langmuir单分子层吸附原理;随着粒径的减小,其最大吸附容量及吸附速率均有明显的提高.试验中粒径为0.038～0.050mm的La2O3·nH2O粒径为 > 0.500～0.710mm的La2O3·nH2O相比,前者的最大吸附容量是后者的3.32倍;当平衡ρ(氟)为1 mg,L时,前者计算所得的吸附容量是后者的10.13倍.与活性氧化铝相比,当平衡ρ(氟)为1mg/L时,相同粒径的La2O3·nH2O的吸附容量是活性氧化铝的2.55～13.88倍.     

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     

O3/H2O2法灭活水中剑水蚤类浮游动物

为解决水源水中孳生的水蚤类浮游动物难以被常规的水处理工艺有效地去除,困扰水厂正常生产运行的问题,进行了O₃氧化、H₂O₂氧化和O₃/H₂O₂高级氧化对水体中剑水蚤类浮游动物灭活效果的试验研究.发现3种方法中,O₃/H₂O₂联合时除蚤效果最佳,在蒸馏水中投量为O31.0mg/L、H₂O₂4mg/L时,接触30min达到100%的灭蚤率;单独O₃氧化效果也较好,投加1.0mg/L的灭蚤率为80%;H₂O₂氧化效果不理想,投加4mg/L几乎无灭蚤效果.进而考察确定了O₃/H₂O₂灭活剑水蚤的最佳工艺条件为:先加O₃后加H₂O₂,投加间隔时间30～60s为宜;并探讨了H₂O₂投量、水体pH值以及有机物含量对O₃/H₂O₂系统灭活剑水蚤效果的影响.试验中发现H₂O₂投量在4～10mg/L之间效果无较大变化,有机物含量对灭蚤影响较大,pH值的影响则较小.最后对O₃/H₂O₂预氧化与水处理混凝沉淀工艺的协同除蚤效能进行了考察.结果表明,O₃/H₂O₂预氧化与水处理混凝沉淀工艺的协同作用将会进一步提高除蚤的效果.     

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.     

On-going nitrification in chloraminated drinking water distribution system (DWDS) is conditioned by hydraulics and disinfection strategies

Within the drinking water distribution system (DWDS) using chloramine as disinfectant, nitrification caused by nitrifying bacteria is increasingly becoming a concern as it poses a great challenge for maintaining water quality. To investigate efficient control strategies, operational conditions including hydraulic regimes and disinfectant scenarios were controlled within a flow cell experimental facility. Two test phases were conducted to investigate the effects on the extent of nitrification of three flow rates (Q = 2, 6, and 10 L/min) and four disinfection scenarios (total Cl₂=1 mg/L, Cl₂/NH₃-N=3:1; total Cl₂=1 mg/L, Cl₂/NH₃-N=5:1; total Cl₂=5 mg/L, Cl₂/NH₃-N=3:1; and total Cl₂=5 mg/L, Cl₂/NH₃-N=5:1). Physico-chemical parameters and nitrification indicators were monitored during the tests. The characteristics of biofilm extracellular polymetric substance (EPS) were evaluated after the experiment. The main results from the study indicate that nitrification is affected by hydraulic conditions and the process tends to be severe when the fluid flow transforms from laminar to turbulent (2300<Re<4000). Increasing disinfectant concentration and optimizing Cl₂/NH₃-N mass ratio were found to inhibit nitrification to some extend when the system was running at turbulent condition (Q = 10 L/min, Re = 5535). EPS extracted from biofilm that was established at the flow rate of 6 L/min had greater carbohydrate/protein ratio. Furthermore, several nitrification indicators were evaluated for their prediction efficiency and the results suggest that the change of nitrite, together with total organic carbon (TOC) and turbidity can indicate nitrification potential efficiently.     

Hepatitis A Virus Disinfection in Water by Solar Photo–Fenton Systems

This study evaluates and compares the effectiveness of solar photo–Fenton systems for the inactivation of hepatitis A virus (HAV) in water. The effect of solar irradiance, dark- Fenton reaction and three different reactant concentrations (2.5/5, 5/10 and 10/20 mg/L of Fe²⁺/H₂O₂) on the photo–Fenton process were tested in glass bottle reactors (200 mL) during 6 h under natural sunlight. Disinfection kinetics were determined both by RT-qPCR and infectivity assays. Mean water temperatures ranged from 25 to 27.3 °C, with a maximum local noon UV irradiances of 22.36 W/m². Photo–Fenton systems yielded increased viral reduction rates in comparison with the isolated effect under the Fenton reaction in darkness (negligible viral reduction) or the solar radiation (0.25 Log of RNA reduction). With the highest concentration employed (10–20 mg/L Fe²⁺–H₂O₂), an average RNA reduction rate of ~ 1.8 Log (initial concentration of 10⁵ pfu/mL) and a reduction of 80% in the infectivity capacity were reached. Results showed a strong synergistic effect between Fe²⁺/H₂O₂ and sunlight, demonstrating that significant disinfection rates of HAV under photo–Fenton systems may occur with relatively higher efficiency at middle environmental temperatures and without the need for an energy-intensive light source.     

过硫酸盐对全氟辛酸的脱氟效果及其动力学模型

以过硫酸盐（PS）对全氟辛酸（PFOA）进行脱氟,考察脱氟率与初始pH值（1~12）、PS初始浓度（0~400.0mmol/L）、温度（25.0~60.0℃）和反应时间（0~24h）的关系,结果表明：初始pH值、PS初始浓度和温度对脱氟率有明显的影响,脱氟率最高可达86.52%;初始pH值为1.5~3的条件明显有利于PFOA的脱氟,而初始pH值为1或12的条件不利于PFOA的脱氟;脱氟动力学模型ln（1-φ）=-k_obst可以很好地描述脱氟率φ与反应时间t、温度和PS初始浓度的关系.     

Magnetically recoverable Fe3O4@polydopamine nanocomposite as an excellent co-catalyst for Fe3+ reduction in advanced oxidation processes

Advanced oxidation processes are widely applied to removal of persistent toxic substances from wastewater by hydroxyl radicals(·OH),which is generated from hydrogen peroxide(H_2O_2) decomposition.However,their practical applications have been hampered by many strict conditions,such as iron sludge,rigid pH condition,large doses of hydrogen peroxide and Fe~(2+),etc.Herein,a magnetically recyclable Fe_3O_4@polydopamine(Fe_3O_4@PDA) coreshell nanocomposite was fabricated.As an excellent reducing agent,it can convert Fe~(3+)to Fe~(2+).Combined with the coordination of polydopamine and ferric ions,the production of iron sludge is inhibited.The minimum concentration of hydrogen peroxide(0.2 mmol/L and Fe~(2+)(0.18 mmol/L)) is 150-fold and 100-fold lower than that of previous reports,respectively.It also exhibits excellent degradation performance over a wide pH range from 3.0 to 9.0.Even after the tenth recycling,it still achieves over 99% degradation efficiency with the total organic carbon degradation rate of 80%,which is environmentally benign and has a large economic advantage.This discovery paves a way for extensive practical application of advanced oxidation processes,especially in environmental remediation.     

Decontamination of alachlor herbicide wastewater by a continuous dosing mode ultrasound/Fe2+/H2O2 process

We used a ultrasound/Fe2+/H2O2 process in continuous dosing mode to degrade the alachlor.Experimental results indicated that lower pH levels enhanced the degradation and mineralization of alachlor. The maximum alachlor degradation(initial alachlor concentration of 50 mg/L) was as high as 100% at pH 3 with ultrasound of 100 Watts, 20 mg/L of Fe2+, 2 mg/min of H2O2 and 20℃ within60 min reaction combined with 46.8% total organic carbon removal. Higher reaction temperatures inhibited the degradation of alachlor. Adequate dosages of Fe2+and H2O2 in ultrasound/Fe2+/H2O2process not only enhance the degradation efficiency of alachlor but also save the operational cost than the sole ultrasound or Fenton process. A continuous dosing mode ultrasound/Fe2+/H2O2 process was proven as an effective method to degrade the alachlor.     

Treatability studies of naphthalene in soil,water and air with persulfate activated by iron(Ⅱ)

Chemical oxidation was applied to an artificially contaminated soil with naphthalene (NAP). Evaluation of NAP distribution and mass reduction in soil, water and air phases was carried out through mass balance. Evaluation of NAP distribution and mass reduction in soil, water and air phases was carried out through mass balance. The importance of the air phase analysis was emphasized by demonstrating how NAP behaves in a sealed system over a 4 hr reaction period. Design of Experiments method was applied to the following variables: sodium persulfate concentration [SP], ferrous sulfate concentration [FeSO₄], and pH. The system operated with a prefixed solid to liquid ratio of 1:2. The following conditions resulted in optimum NAP removal [SP] = 18.37 g/L, [FeSO₄] = 4.25 g/L and pH = 3.00. At the end of the 4 hr reaction, 62% of NAP was degraded. In the soil phase, the chemical oxidation reduced the NAP concentration thus achieving levels which comply with Brazilian and USA environmental legislations. Besides the NAP partitioning view, the monitoring of each phase allowed the variabilities assessment over the process, refining the knowledge of mass reduction. Based on NAP distribution in the system, this study demonstrates the importance of evaluating the presence of semi-volatile and volatile organic compounds in the air phase during remediation, so that there is greater control of the system as to the distribution and presence of the contaminant in the environment. The results highlight the importance of treating the contaminant in all its phases at the contaminated site.     

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.      

Decomposition of perfluorooctanoic acid by microwaveactivated persulfate: Effects of temperature, pH, and chloride ions

Microwave-hydrothermal treatment of persistent and bioaccumulative perfluorooctanoic acid (PFOA) in water with persulfate (S₂O₈²⁻) has been found effective. However, applications of this process to effectively remediate PFOA pollution require a better understanding on free-radical scavenging reactions that also take place. The objectives of this study were to investigate the effects of pH (pH = 2.5, 6.6, 8.8, and 10.5), chloride concentrations (0.01–0.15 mol·L⁻¹), and temperature (60°C, 90°C, and 130°C) on persulfate oxidation of PFOA under microwave irradiation. Maximum PFOA degradation occurred at pH 2.5, while little or no degradation at pH 10.5. Lowering system pH resulted in an increase in PFOA degradation rate. Both high pH and chloride concentrations would result in more scavenging of sulfate free radicals and slow down PFOA degradation. When chloride concentrations were less than 0.04 mol·L⁻¹ at 90°C and 0.06 mol·L⁻¹ at 60°C, presence of chloride ions had insignificant impacts on PFOA degradation. However, beyond these concentration levels, PFOA degradation rates reduced significantly with an increase in chloride concentrations, especially under the higher temperature.     

UV/H2O2工艺降解微囊藻毒素-LR

采用UV/H₂O₂联合工艺,研究了光强、初始浓度、H₂O₂投加量、pH及阴离子对微囊藻毒素-LR (MC-LR)去除率的影响.结果表明,单独H₂O₂对MC-LR基本无去除效果;单独UV工艺可以一定程度上降解MC-LR;而UV/H₂O₂联合工艺由于发生协同作用明显提高降解效率.试验发现,随着光强的增大,MC-LR的去除率不断提高;随着MC-LR初始浓度的增大,其去除率不断降低;随着H₂O₂投加量的增大,降解速率常数逐渐增大,当H₂O₂投加量由1 mmol/L增大到3 mmol/L时,降解速率常数由0.084 4上升到0.166 4;当pH为3.13时,在相同条件下MC-LR的去除效果最好;阴离子的投加不利于MC-LR的降解,其中CO^2-₃、NO^-₃影响最大.     

Fenton氧化/混凝协同处理焦化废水生物出水的研究

对Fenton氧化/混凝协同处理焦化废水生物出水的方法进行了研究,在综合考虑经济性和去除效果的前提下,提出了反应的最佳条件:H₂O₂投加量为220 mg/L,Fe²⁺投加量为180 mg/L,聚丙烯酰胺投加量为4.5 mg/L,反应时间为0.5h,pH=7.最终COD去除率可达44.5%,色度可以降为35倍,出水符合国家污水排放二级标准.同时,通过分析分子量分布和小分子有机物组成,揭示了Fenton氧化/混凝协同处理焦化废水生物出水的污染物变化规律.结果表明焦化废水经过Fenton氧化/混凝协同处理后,其出水可达到国家二级排放标准,并且处理成本相对较低,具有实际应用的前景.     

UV/H2O2降解美罗培南的影响因素及毒性研究

利用波长为254 nm的紫外灯活化过氧化氢(H_2O_2)氧化降解美罗培南(MPN),考察了H_2O_2投加量、初始pH值、水中常见共存阴离子(Cl~-、HCO~-_3、NO~-_3)和天然有机化合物(NOM)等重要影响因素对MPN降解的影响.结果表明,紫外光功率为4 W,初始pH为7.0,n(H_2O_2)/n(MPN)=20∶1时,反应20 min后,MPN的降解率达到97.8%.H_2O_2投加量的增加会加快MPN的降解速率,Cl~-和HCO~-_3对UV/H_2O_2体系中MPN去除效果的影响较小,极少量的NO~-_3会促进MPN的降解,当NO~-_3的浓度≥10 mg·L~(-1)时,MPN的降解受到抑制,且离子浓度越高,抑制程度表现越明显.NOM的存在对MPN的降解有抑制作用.与纯水相比,MPN在实际水体中的去除受到抑制,归因于水体基质的影响.大肠杆菌的急性毒性实验研究表明,MPN的中间转化产物保留了一些抗菌性能,但光解的最终产物无抗菌性能.     

O3/H2O2降解Atrazine效能研究

利用O₃/H²O²降解莠去津,对氧化产物进行了色谱分析,以评价该体系降解莠去津效能.莠去津初始浓度2 mg/L,7.5 mg/L的O₃单独氧化去除率为27.2%;相同O₃投量下,H²O²/O₃摩尔比0.75时,5 min莠去津的去除率最高可达96.5%,表明H²O²/O₃体系对莠去津的去除效果良好,降解速度快.以离子色谱对产物的离子进行分析,莠去津浓度下降的同时,硝酸根和氯离子浓度增高.GC-MS检测的产物和对LC-MS谱图的分析表明,有机产物中存在脱乙基、脱异丙基和脱氯莠去津,说明H²O²/O₃并不能彻底氧化莠去津,因此工程中作为主要去除单元或突发性污染事件的应急手段可能还需要与活性炭等单元联用.     

Oxidative removal of acetaminophen using zero valent aluminum-acid system: Efficacy, influencing factors, and reaction mechanism

Commercial available zero valent aluminum under air-equilibrated acidic conditions (ZVAl/H⁺/air system) demonstrated an excellent capacity to remove aqueous organic compounds. Acetaminophen (ACTM), the active ingredient of the over-the-counter drug Tylenol^®, is widely present in the aquatic environment and therefore the treatment of ACTM-contaminated water calls for further research. Herein we investigated the oxidative removal of ACTM by ZVAl/H⁺/air system and the reaction mechanism. In acidic solutions (pH < 3.5), ZVAl displayed an excellent capacity to remove ACTM. More than 99% of ACTM was eliminated within 16 hr in pH 1.5 reaction solutions initially containing 2.0 g/L aluminum and 2.0 mg/L ACTM at 25 ± 1\textcelsius. Higher temperature and lower pH facilitated ACTM removal. The addition of different iron species Fe⁰, Fe²⁺ and Fe³⁺ into ZVAl/H⁺/air system dramatically accelerated the reaction likely due to the enhancing transformation of H₂O₂ to HO. via Fenton's reaction. Furthermore, the primary intermediate hydroquinone and the anions formate, acetate and nitrate, were identified and a possible reaction scheme was proposed. This work suggested that ZVAl/H⁺/air system may be potentially employed to treat ACTM-contaminated water.