废水中α-氯代环己基苯基甲酮的电化学降解

采用石墨电极对含α-氯代环己基苯基甲酮的氯化清洗水进行电化学降解。结果表明,电化学降解对COD的去除效果非常明显,并且随着电流密度增加,COD的去除效率逐渐升高,电流密度由15 mA/cm2增加至100 mA/cm2, COD的去除率从39.7%升高到72.3%;电化学降解作用下,水样可生化性显著提高,降解2 h后,(BOD5)/(COD)由原水的0.22提高到0.46;电化学降解过程中,COD的降解遵循零级反应动力学方程;此外,还对电化学降解过程中α-氯代环己基苯基甲酮的降解途径进行了推测。     

Hydrothermal-treated Pt/Al2O3 as an excellent catalyst for toluene total oxidation

The preparation of highly active supported noble metal catalysts with a low noble metal loading has always been the ultimate goal of researchers working on catalysis. Hydrothermally treated Pt/Al₂O₃ (Pt/Al₂O₃-H) exhibits better catalytic activity than that (Pt/Al₂O₃-C) treated via the conventional calcination approach. At the high space velocity of 100,000 mL/(g∙hr), the temperature that correspond to 50% toluene conversion (T₅₀) of Pt/Al₂O₃-H is 115°C lower than that of Pt/Al₂O₃-C, and the turnover frequency (TOF) value can reach 0.0756 sec⁻¹. The mechanism by which the hydrothermal approach enhances Pt/Al₂O₃ activity has been investigated. The structure associated with the high catalytic activity of Pt nanoparticles (NPs) can be retained via hydrothermal treatment. Furthermore, the support is transformed to AlO(OH) with numerous surface hydroxyl groups, which in turn can facilitate the adsorption of toluene. And the synergistic effects of Pt NPs and AlO(OH) increases the contents of Pt in oxidation state and active oxygen, which are beneficial for toluene oxidation.     

Theoretical insights into the degradation mechanisms, kinetics and eco-toxicity of oxcarbazepine initiated by OH radicals in aqueous environments

As an anticonvulsant, oxcarbazepine (OXC) has attracted considerable attention for its potential threat to aquatic organisms. Density functional theory has been used to study the mechanisms and kinetics of OXC degradation initiated by OH radicals in aqueous environment. A total of fourteen OH-addition pathways were investigated, and the addition to the C8 position of the right benzene ring was the most vulnerable pathway, resulting in the intermediate IM8. The H-abstraction reactions initiated by OH radicals were also explored, where the extraction site of the methylene group (C14) on the seven-member carbon heterocyclic ring was found to be the optimal path. The calculations show that the total rate constant of OXC with OH radicals is 9.47 × 10⁹ (mol/L)⁻¹sec⁻¹, and the half-life time is 7.32 s at 298 K with the [·OH] of 10⁻¹¹ mol/L. Moreover, the branch ratio values revealed that OH-addition (89.58%) shows more advantageous than H-abstraction (10.42%). To further understand the potential eco-toxicity of OXC and its transformation products to aquatic organisms, acute toxicity and chronic toxicity were evaluated using ECOSAR software. The toxicity assessment revealed that most degradation products such as OXC-2OH, OXC-4OH, OXC-1O-1OOH, and OXC-1OH' are innoxious to fish and daphnia. Conversely, green algae are more sensitive to these compounds. This study can provide an extensive investigation into the degradation of OXC by OH radicals and enrich the understanding of the aquatic oxidation processes of pharmaceuticals and personal care products (PPCPs).     

Characterizing the optimal operation of photocatalytic degradation of BDE-209 by nano-sized TiO2

Brominated flame retardants have been widely used in industry. There is a rapid growing public concern for their availabilities in the environment. Advanced oxidation process (AOP) is a promising and efficient technology which may be used to remove emerging chemicals such as brominated flame retardants. This project aims at investigating optimal operational conditions for the removal of BDE-209 using nano-scaled titanium(IV) oxide. The residual PBDE congeners after photocatalytical degradation of BDE-209 by TiO₂ were analysed by gas chromatography-mass spectrometry (GC-MS). It was found that the degradability of BDE-209 by TiO₂ was attributed to its photocatalytic activity but not the small size of the particles. The half-life of removing BDE-209 by TiO₂ was 3.05 days under visible light. Tetra- and penta-BDEs were the major degraded products of BDE-209. Optimum conditions for photocatalytical degradation of BDE-209 was found to be at pH 12 (93% ± 1%), 5, 10, 20 mg/L (93.0% ± 1.70%, 91.6% ± 3.21%, 91.9% ± 0.952%, respectively), respectively of humic acid and in the form of anatase/rutile TiO₂ (82% ± 3%). Hence, the efficiency of removing BDE-209 can be maximized while being cost effective at the said operating conditions.     

Fractionation of residual Al in natural water treatment from reservoir with poly-aluminum-silicate-chloride (PASiC): Effect of OH/Al, Si/Al molar ratios and initial pH

An aluminum fractionation study was conducted for a surface reservoir water treatment to understand the performance of poly-aluminum-silicate-chloride (PASiC) in terms of the residual Al fractions as a function of initial pH. The coagulation performance expressed as turbidity and organic matter removal was established as supporting data. Some extra data were evaluated in terms of the residual Al ratio of the composite PASiC coagulant. The main residual Al sources were the Al fractions derived from the use of PASiC. The turbidity and organic matter removal ability was optimal at initial pH 6.00-7.00, while the concentrations of various residual Al species and the residual Al ratio of PASiC were minimal at an initial pH range of 7.00-8.00. Under the conditions of OH/Al molar ratio = 2.00 and Si/Al molar ratio = 0.05, PASiC had superior coagulation performance and comparatively low residual Al concentrations. The Al fraction in the composite PASiC coagulant seldom remained under such conditions. Experimental data also indicated that the suspended (filterable) Al fraction was the dominant species, and organic-bound or organo-Al complex Al was considered to be the major species of dissolved Al in water treated by PASiC coagulation. Additionally, the dissolved inorganic monomeric Al species dominated the dissolved monomeric Al fraction.     

Adsorption characteristics and mechanism of Cr （Ⅵ） on chitoan-yttrium porous microsphere

以壳聚糖和Y2（OH）5NO3为原料通过乳液交联法制备了壳聚糖-钇（Ch—Y）复合微球,通过扫描电镜、透射电镜、X射线衍射、红外光谱等方法对其表面形貌、结构进行了表征.探讨了溶液的pH值、反应时间、投加量、离子初始浓度对其吸附性能的影响.研究结果表明,壳聚糖-钇（Ch—Y）复合微球在pH值为3的酸性环境中对Cr（Ⅵ）保持了较高的吸附能力,吸附容量为52.39mg·g-1,其吸附行为符合Langmuir吸附等温模型;通过吸附机理的研究,发现壳聚糖-钇（Ch—Y）对Cr（Ⅵ）吸附是化学吸附静电吸附协同氧化Cr（Ⅵ）离子作用来实现的.     

超声波/零价铁协同体系作用机理探讨

在超声波/零价铁协同体系中,探讨了OH.的产生途径及其影响因素,并分析了Fe0表面形态变化。结果表明:在超声波/零价铁体系中,羟基自由基的产生途径主要有四种:声空化导致水分子热解、Fenton反应、超声波与类Fenton反应的复合效应、铁粉颗粒效应;pH值过低或过高都不利于羟基自由基产生;当铁粉投加量为2.0g/L时最有利于羟基自由基产生;超声波通过冲刷、碎裂、清洗、气蚀和熔合等多种效应,活化和增强铁粉的表面性能。     

光助芬顿反应催化降解气体中甲苯

以甲苯作为挥发性有机污染物(VOCs)的代表,利用连续进气动态实验装置,研究光助芬顿反应降解气体中甲苯的作用.考察了芬顿试剂溶液初始p H、H2O2浓度、Fe2+浓度以及甲苯初始浓度对降解甲苯的影响,并利用在线质谱和色谱对产物进行了定性、定量分析.结果表明,紫外光照加快了羟基自由基的生成,显著提高了气体中甲苯的去除率;p H=3.0、H2O2浓度为20 mmol·L-1、Fe2+浓度为0.3 mmol·L-1的条件下,甲苯去除率最高;当甲苯初始浓度为260 mg·m-3时,去除率能够达到98%;光助芬顿反应催化降解气体中甲苯实验未检测到CO2之外的中间产物,CO2产率分析表明去除的甲苯全部转化为CO2.     

生物炭中持久性自由基对秀丽隐杆线虫的毒性

为了评价生物炭的使用对生态系统,尤其是对土壤无脊椎动物的毒性影响,使用模式生物秀丽隐杆线虫（Caenorhabditis elegans,C.elegans）来评估生物炭的环境风险.观察了生物炭原样、生物炭颗粒物和生物炭浸提液对线虫神经行为学评价指标（身体摆动频率、相对运动长度、排泄间隔时间、碰触反应率和化学感知行为指数）的影响;并结合生物炭的理化性质、非金属元素组成和重金属元素含量以及环境持久性自由基（EPFRs）的强度,评估生物炭对线虫的生物毒性.结果显示,EPFRs信号强的生物炭和颗粒物对秀丽隐杆线虫有一定的毒物兴奋效应,EPFRs信号微弱的浸提液无显著性影响.因此,生物炭中的EPFRs对秀丽隐杆线虫有潜在的神经毒性作用.     

光电催化氧化处理中各类活性物质的氧化机理

为了深入研究其中各类活性物质氧化机理,以难降解的3,4-二甲基苯胺（3,4-DMA）废水作为研究对象,通过研究不同抑制剂条件下的动力学规律,并以贡献度（k_f/K）来量化各活性物质的作用效果,得出氯类活性物质的贡献度为89.03%,羟基自由基（·OH）的贡献度为6.24%,而空穴和阳极直接氧化贡献度可以忽略.采用三聚氰胺法、二甲亚砜（DMSO）法和DPD法定性定量测定了空穴、·OH和自由氯的含量,结果表明：较高浓度的氯化钠降低了空穴和·OH的贡献度;·OH的产量符合零级动力学规律,其产生速率为0.106mg/（L·min）;自由氯的累积浓度分为3个阶段,第3阶段累积速率为0.159mg/（L·min）.自由氯仅占氯类活性物质氧化体系的一小部分,其他含氯氧化物质和氯类自由基的氧化占重要地位.通过GC-MS、UV-vis和TOC检测,发现在反应10.0min前,主要通过氯类活性物质对侧链的快速攻击,使3,4-DMA转化为苯甲醛等易分解的苯环类物质;10.0min后,主要通过·OH对苯环大π键的攻击,使苯环类物质转化为小分子物质,然后继续被·OH氧化直到矿化.