对位酯废水的光催化降解研究

研究了对位酯生产废水的初步处理方案.先将对位酯废水进行中和、冷冻除盐、加CaO沉淀、过滤等预处理(预处理后COD 40 352 mg/L;SO42- 9 577 mg/L;NH3-N 21 mg/L),再采用纳米光催化降解以及BaCl2进行处理,TiO2浓度为2 g/L时处理效果较好(COD 30 325 mg/L;SO42- 880 mg/L;NH3-N 140 mg/L).废水经铁炭微电解及CaO处理后,再进行光催化降解可以达到更好的处理效果,COD降为21 224 mg/L.废水经微电解、Fenton氧化和光催化联用处理后,COD降为20 800 mg/L.     

多能场协同紫外光催化降解甲基橙的实验研究

以甲基橙为模拟废水,负载型纳米TiO2为光催化剂,在自制的多能场组合反应器中,初步研究了电场和超声场协同紫外光催化降解水中甲基橙的特点和规律。结果表明,在偏置电场电压为20 v,超声场声频为21.33 kHz、声强为0.375 W/cm2,紫外光波长为366 nm,功耗为O.25 W/mL,TiO2催化降解负荷为1.25 mL/cm2的条件下,对浓度为4 mg/L的甲基橙溶液分别处理30 min和90 min,脱色率分别可达91.67％和95.36％;比单一紫外光催化降解脱色率分别提高86.59％和86.79％。     

煤热解废水典型工艺流程中芳香化合物的降解特性

选取河南某低阶煤热解废水处理典型工艺流程为研究对象,探讨了各单元对芳香化合物的降解特性。通过降解效能对比发现,SBR工艺对酚类(96.13%)和氮杂环类化合物(78.13%)的降解能力最高,故其为芳香化合物降解的核心单元。通过凝胶色谱、紫外-可见光光谱和三维荧光光谱对全流程废水特性的表征,推测出其分子质量在3 kDa左右,荧光峰在Ex/Em=(300～370) nm/(400～450) nm的腐殖酸物质是煤热解废水关键的难生化物质。各单元的统计分析结果表明,废水处理效果不佳的原因在于酸化、气浮、好氧及强氧化单元。在此基础上,根据最新研究结果和成功案例对现有工艺提出了针对性改进方案。以上结果可为类似的废水处理工程提供参考。     

TiO2/CdS复合半导体光催化剂降解甲基橙的实验研究

采用Sol-Gel法制备TiO2/CdS复合半导体光催化剂,以8 W-365 nm的紫外灯为光源、甲基橙溶液模拟染料废水、在自制的光催化反应器中研究TiO2/CdS的光催化活性和光催化降解甲基橙的特点和规律.结果表明,当CdS掺入量为0.5%(摩尔比)时,TiO2/CdS的光催化活性最高;当CdS的掺入量＞3.5%(摩尔比)时,TiO2/CdS光催化剂的光催化活性低于TiO2的光催化活性;对初始浓度为15 mg/L的甲基橙溶液处理2.5 h后,脱色率可达44%;甲基橙的光催化降解反应符合Y=A B1×X B2×X2动力学模型.     

Controlled synthesis of uniform BiVO4 microcolumns and advanced visible-light-driven photocatalytic activity for the degradation of metronidazole-contained wastewater

Well-defined, uniform bismuth vanadate (BiVO₄) microcolumns were synthesized through a refined hydrothermal route. During the fabrication process, a detailed orthogonal design on the synthetic conditions was performed, aiming to optimize the experimental parameters to produce BiVO₄ materials (BiVO₄ (Opt.)) with the most prominent visible-light-driven photocatalytic efficiency, where the catalytic activities of the synthesized materials were evaluated via the decolorization of methylene blue under visible light irradiation. The BiVO₄ (Opt.) were then targetedly produced according to the determined optimal conditions and well characterized by X-ray diffraction, scanning electron microscopy, transmission electron microscopy, ultraviolet and visible diffuse-reflectance spectroscopy and photoluminescence spectroscopy. Compared with the commercial P25-TiO₂ photocatalysts, the as-synthesized BiVO₄ (Opt.) displayed superior visible-light-driven photocatalytic activities for the degradation of metronidazole-contained wastewater with the presence of H₂O₂. The degradation efficiency of metronidazole reached up to 70 % within 180 min, leading to a brief speculation on the possibly major steps of the visible-light-driven photocatalytic process. The current study provides a distinctive route to design novel shaped BiVO₄ architectures with advanced photocatalytic capacities for the treatment of organic pollutants in the aqueous environment.     

Metal-free graphene-based catalytic membranes for persulfate activation toward organic pollutant removal: a review

Owing to their ultrathin two-dimensional structure and efficient catalytic ability for persulfate activation, graphene-based nanocarbons exhibit considerable application potential in fabricating carbonaceous composite membranes for in situ catalytic oxidation to remove organic pollutants. This approach offers significant advantages over conventional batch systems. However, the relationships between the physicochemical properties of carbon mats and performance of graphene-based catalytic membranes in water purification remain ambiguous. Herein, we summarize the main mechanisms of in situ catalytic oxidation and the facile fabrication strategies of carbonaceous composite membranes. Different factors influencing the performance of graphene-based catalytic membranes are comprehensively discussed. The defective level, heteroatom doping, and stacking morphology of carbon mats and operational conditions during filtration play critical roles in the oxidative degradation of target pollutants. Long-term operation leads to the deterioration of catalytic activity and transmembrane pressure, especially in the complex water matrix. Finally, the present challenges and future perspectives are presented to improve the anti-fouling performance and catalytic stability of membranes and develop scalable fabrication methods to promote the engineering applications of in situ catalytic oxidation in real water purification.

     

Degradations of endocrine-disrupting chemicals and pharmaceutical compounds in wastewater with carbon-based nanomaterials: a critical review

Environmental Science and Pollution Research - Although water occupies 75% of the earth’s surface, only 0.0067% of the total water is available for human activities. These statistics further...     

Nanomaterials photocatalytic activities for waste water treatment: a review

Water is necessary for the survival of life on Earth. A wide range of pollutants has contaminated water resources in the last few decades. The presence of contaminants incredibly different dyes in waste, potable, and surface water is hazardous to environmental and human health. Different types of dyes are the principal contaminants in water that need sudden attention because of their widespread domestic and industrial use. The toxic effects of these dyes and their ability to resist traditional water treatment procedures have inspired the researcher to develop an eco-friendly method that could effectively and efficiently degrade these toxic contaminants. Here, in this review, we explored the effective and economical methods of metal-based nanomaterials photocatalytic degradation for successfully removing dyes from wastewater. This study provides a tool for protecting the environment and human health. In addition, the insights into the transformation of solar energy for photocatalytic reduction of toxic metal ions and photocatalytic degradation of dyes contaminated wastewater will open a gate for water treatment research. The mechanism of photocatalytic degradation and the parameters that affect the photocatalytic activities of various photocatalysts have also been reported.

     

Performance evaluation of a continuous flow photocatalytic reactor for wastewater treatment

A novel photocatalytic reactor for wastewater treatment was designed and constructed. The main part of the reactor was an aluminum tube in which 12 stainless steel circular baffles and four quartz tube were placed inside of the reactor like shell and tube heat exchangers. Four UV–C lamps were housed within the space of the quartz tubes. Surface of the baffles was coated with TiO₂. A simple method was employed for TiO₂ immobilization, while the characterization of the supported photocatalyst was based on the results obtained through performing some common analytical methods such as X-ray diffraction (XRD), scanning electron microscope (SEM), and BET. Phenol was selected as a model pollutant. A solution of a known initial concentration (20, 60, and 100 ppmv) was introduced to the reactor. The reactor also has a recycle flow to make turbulent flow inside of the reactor. The selected recycle flow rate was 7?×?10^?5 m³.s^?1, while the flow rate of feed was 2.53?×?10^?7, 7.56?×?10^?7, and 1.26?×?10^?6 m³.s^?1, respectively. To evaluate performance of the reactor, response surface methodology was employed. A four-factor three-level Box–Behnken design was developed to evaluate the reactor performance for degradation of phenol. Effects of phenol inlet concentration (20–100 ppmv), pH (3–9), liquid flow rate (2.53?×?10^?7?1.26?×?10^?6 m³.s^?1), and TiO₂ loading (8.8–17.6 g.m^?2) were analyzed with this method. The adjusted R ² value (0.9936) was in close agreement with that of corresponding R ² value (0.9961). The maximum predicted degradation of phenol was 75.50 % at the optimum processing conditions (initial phenol concentration of 20 ppmv, pH?～?6.41, and flow rate of 2.53?×?10^?7 m³.s^?1 and catalyst loading of 17.6 g.m^?2). Experimental degradation of phenol determined at the optimum conditions was 73.7 %. XRD patterns and SEM images at the optimum conditions revealed that crystal size is approximately 25 nm and TiO₂ nanoparticles with visible agglomerates distribute densely and uniformly over the surface of stainless steel substrate. BET specific surface area of immobilized TiO₂ was 47.2 and 45.8 m² g^?1 before and after the experiments, respectively. Reduction in TOC content, after steady state condition, showed that maximum phenol decomposition occurred at neutral condition (pH?～?6). Figure

The schematic view of the experimental set-up     

TiO2/GeO2复合膜光催化氧化降解农药废水的研究

提出了一种新的TiO2/GeO2复合膜圆形光催化氧化反应器,研究了该反应器对经物化处理后的农药废水进行降解的过程。研究表明,光催化氧化的最佳条件是锌片镀TiO2/GeO2复合膜、pH=6.7、过氧化氢（H2O2）浓度为400 mg/L。并对其他氧化剂对该过程的影响进行了探讨。有机废水通过该反应器处理后,其COD值降为57mg/L。能使有机污染物全部降解为小分子无机物,废水达到国家一级排放标准。     

Cyclodextrin-based adsorbents for the removal of pollutants from wastewater: a review

Environmental Science and Pollution Research - Water is a vital substance that constitutes biological structures and sustains life. However, water pollution is currently among the major...     

Post-treatment of bio-treated acrylonitrile wastewater using UV/Fenton process: degradation kinetics of target compounds

In this study, post-treatment of bio-treated acrylonitrile wastewater was performed using the UV/Fenton process. Five target compounds (furmaronitrile, 3-pyridinecarbonitrile, 1,3-dicyanobenzene, 5-methyl-1H-benzotriazole, and 7-azaindole) were selected as target compounds and their degradation kinetics were examined. Under optimal reaction conditions (H₂O₂ dosage 3.0 mM, Fe²⁺ dosage 0.3 mM, and initial pH 3.0), more than 85% of total organic carbon (TOC) was eliminated in 30 min when a 10-W UV lamp was employed, and the electrical energy per order of magnitude for TOC removal was as low as 2.96 kWh m^?3. Furthermore, the target compounds and the toxicity were largely removed from the bio-treated effluent. Size exclusion chromatography with organic carbon detector analysis revealed that organic components with a wide range of molecular weights were greatly reduced after the UV/Fenton process. A simplified pseudo steady-state (SPSS) model was applied to predict the degradation of target compounds during the UV/Fenton process. The concentrations of generated hydroxyl radicals were estimated to be 3.06 × 10^?12 M, 6.37 × 10^?12 M, and 10.9 × 10^?12 M under 5-, 10-, and 15-W UV lamps, respectively. These results demonstrate that the proposed SPSS model fitted well with experimental data on the post-treatment of real wastewater, and consequently indicate that this model can be a useful tool in the prediction of degradation of target compounds during the UV/Fenton process.

     

Treatment of electroplating industry wastewater: a review on the various techniques

Environmental Science and Pollution Research - Water pollution by recalcitrant compounds is an increasingly important problem due to the continuous introduction of new chemicals into the...     

Integrated process approach for degradation of p-cresol pollutant under photocatalytic reactor using activated carbon/TiO2 nanocomposite: application in wastewater treatment

Environmental Science and Pollution Research - Over the years, biodegradation has been an effective technique for waste water treatment; however, it has its own limitations. In order to achieve a...     

光催化反应器在污水处理中的研究现状与发展趋势

根据光催化反应的光源不同 ,将多相光催化反应器分为聚光式反应器和非聚光式反应器。本文主要介绍了国内外近年来有关污水处理中的光催化反应器研制与应用的进展情况 ,同时展望其发展趋势。论述了适用于工业化光催化反应器的特点及今后的发展方向     

Microbial degradation of phenols: a review

The microbial degradation of phenols has been reviewed including the phenol-degrading microbes, factors affecting degradability, and the use of biotechnology with emphasis on degradation mechanisms and their kinetics. The mechanism of microbial degradation depends on aerobic and anaerobic conditions. Under aerobic conditions, degradation of phenol was shown to be initiated by oxygenation into catechols as intermediates followed by a ring cleavage at either the ortho or meta position, depending on the type of strain. Anaerobic biodegradation of phenol occurs by carboxylation followed by dehydroxylation (reducing reaction) and dearomatisation. It was also clear that the parameters used in the Haldane model are not constants but vary, hence it may never be possible to describe the kinetic properties of a microbial cell with a single set of constants.     

Treatment of wastewater by electrocoagulation: a review

The electrocoagulation (EC) process is an electrochemical means of introducing coagulants and removing suspended solids, colloidal material, and metals, as well as other dissolved solids from water and wastewaters. The EC process has been successfully employed in removing pollutants, pesticides, and radionuclides. This process also removes harmful microorganisms. More often during EC operation, direct current is applied and electrode plates are sacrificed (dissolved into solution). The dissolution causes an increased metal concentration in the solution that finally precipitates as oxide precipitates. Due to improved process design and material of construction, the EC process is being widely accepted over other physicochemical processes. Presently, this process has gained attention due to its ability to treat large volume and for its low cost. The aim of this study is to review the mechanism, affecting factors, process, and application of the electrocoagulation process.     

Anaerobic treatment of slaughterhouse wastewater: a review

This article presents a review of anaerobic treatment technologies to treat slaughterhouse wastewater including its advantages and disadvantages. Physico-chemical characteristics and biochemical methane potential (BMP) of slaughterhouse wastewater are addressed. Various anaerobic treatment technologies are presented with the related operating parameters, viz., hydraulic retention time (HRT), organic loading rate (OLR), upflow velocity (V_up), and biogas yield vis-a-vis treatment efficiency in terms of chemical oxygen demand (COD). In addition, various factors that affect the anaerobic treatment of slaughterhouse wastewater such as high oil & grease (O & G) concentration in influent, inhibitors, volatile fatty acids (VFAs), and the loading rate are also addressed. The literature review indicated that the slaughterhouse wastewater can be treated effectively by employing any anaerobic treatment technologies at OLRs up to 5 kg COD/m³.d with more than 80% COD removal efficiency without experiencing operational problems. Anaerobic hybrid reactors (AHRs) were found the most effective among various reviewed technologies because of their ability to operate at higher OLRs (8 to 20 kg COD/m³.d) and lower HRTs (8 to 12 hrs).

     

Carbon-based nano-filler in polymeric composites for supercapacitor electrode materials: a review

Environmental Science and Pollution Research - The concept of this paper was to explore the comparative advantage of polymer composite in the formation of a critical part of electrodes, separators,...