高能等离子体分解CO_2气体研究

为治理温室气体ＣＯ_２，本工作在低温常压条件下，利用超高压脉冲电晕放电产生的高能量（２０～５０ｅＶ）非平衡等离子体作用于ＣＯ_２气体分子，使ＣＯ_２分子化学结合键断裂，在定向化学反应作用下，将ＣＯ_２气体分解成单原子气体分子Ｏ_２和单质固体微粒Ｃ。ＣＯ_２分解率在９０％以上。     

Optimized photocatalytic regeneration of adsorption-photocatalysis bifunctional composite saturated with Methyl Orange

Photo-responsive adsorption-photocatalysis nanocomposites are generally used in water and wastewater decontamination; however, the prolonged adsorption capacity of composites and the role of adsorption in concomitant photocatalysis are typically neglected. These composites can be regenerated under light irradiation as their adsorption capacity decreases. Herein, a novel adsorption-photocatalysis bifunctional nanocomposite, Bi-doped TiO₂ supported on powdered activated carbon (Bi₂O₃/TiO₂/PAC), was prepared using the sol-impregnation-hydrothermal procedure. Bi₂O₃/TiO₂/PAC with a secondary calcination temperature of 700°C under a nitrogen atmosphere was selected for maximum adsorption capacity on Methyl Orange (MO). The composite displayed an excellent adsorption capacity and was easily separated and recycled. The results demonstrate that 71.2% photocatalytic regeneration efficiency could be attained under visible light irradiation for 1 hr at an intensity of 750?W/m² and pH 7. Characterization of the as-prepared Bi₂O₃/TiO₂/PAC nanocomposite (700°C) indicates that it possesses a highly specific surface area and great optical properties, showing bifunctional adsorption-photocatalysis characteristics. The p-n heterojunction of the composite played a dominant role in the photocatalytic regeneration process, and effective degradation of MO could be achieved along with composite regeneration.     

杂散电流下新型阻锈剂对混凝土中氯离子扩散的影响

目的探寻混凝土在杂散电流和氯离子耦合作用下的腐蚀规律,研究新型阻锈剂的阻锈性能。方法运用电通量法和RCM法,对20 V杂散电流作用下,混凝土的抗氯离子渗透性能进行表征,设置空白组对照实验,对添加阻锈剂后,混凝土的抗氯离子渗透性能进行效果评价。结果在杂散电流和氯离子的共同作用下,混凝土结构腐蚀的倾向将变大,并且会加速腐蚀反应的进行。混凝土结构在通电48 h后,其电通量高达5778.67 C。与空白组相比,添加阻锈剂混凝土试块的氯离子扩散系数下降45.62%。结论添加4%阻锈剂的混凝土试块有着较好的抵抗氯离子渗透的能力。     

UV强化草酸络合Fe2+活化过硫酸盐氧化苯胺研究

采用UV强化草酸络合Fe2+活化过硫酸钠(PS)氧化降解苯胺,研究了UV光照促进苯胺降解的作用机制,考察了pH、草酸浓度和UV光照强度对PS活化及苯胺降解的影响.结果表明,引入UV光照后,草酸络合Fe2+活化PS体系中的PS活化率和苯胺降解率分别提高了68%和41%.在该过程中,UV可通过光解或光电离水分子产生·OH、促进发生光化学Fenton反应、直接活化PS等作用机制降解苯胺,但通过光化学反应促进Fe2+循环转化是提高PS持续活化效果和苯胺去除的首要作用机制;中碱性及强酸性环境因不利于Fe(C2O4)3-3形成,会对PS活化过程产生抑制,但当初始pH为7和9时,由于PS活化分解促进反应体系pH下降,PS活化及苯胺降解均取得较好效果;草酸浓度的增加有利于PS活化,但当草酸浓度高于2.5 mmol·L~(-1)时,会对SO·-4产生强烈竞争,导致苯胺降解率出现下降;增加UV光照强度能显著促进PS活化和苯胺氧化去除,当UV光照强度达到117μW·cm-2时,反应150 min后,PS的分解率和苯胺的去除率均可达到100%.     

上海港区船舶防污漆中Irgarol 1051的环境风险评价

Irgarol 1051是一种常用于船舶防污漆的杀生活性物质。为了评价船舶防污漆杀生活性物质Irgarol 1051的海洋环境风险,根据ISO 13073-1的评价原则和程序,对其进行环境危害评价、环境暴露评价和风险表征。通过对公共数据库的文献检索获取数据,从理化性质、环境行为、生态毒性3个方面评价Irgarol 1051的环境危害。采用评估因子法计算Irgarol 1051的预测无效应浓度(PNEC)。采用质量守恒法计算Irgarol 1051在海水中的释放率,通过MAMPEC v3.0模型推导上海洋山深水港的集装箱船区、码头、航道等暴露场景的预测环境浓度(PEC)。经过比较上述暴露场景的风险商值(PEC/PNEC)发现,港口的海水相风险商值大于1,Irgarol 1051的环境风险需要关注。     

几种可利用多氯联苯和多溴联苯醚植物内生菌的分离及初步鉴定

采用PDA、NA以及高氏一号培养基,分别从毛白杨、绦柳、荻以及二穗短柄草植株内分离、纯化出37株内生菌,其中34株为细菌,3株为放线菌.以分离纯化得到菌株各自对应的营养培养基并添加不同浓度的污染物对获得的37株内生菌进行污染物的耐受筛选,发现24株分别对20 mg·L-1的aroclor1254和BDE209具有一定的耐受性.利用无机盐培养基并添加污染物作为微生物唯一碳源筛选,发现菌株CPY-4和菌株SGL-1可以在只提供4-BDE的无机盐培养基中存活,菌株CPY-4,SGL-1、菌株4、菌株13可以在提供BDE209和aroclor1254的无机盐培养基中存活.形态学观察和16Sr DNA序列同源性分析,初步确定菌株SGL-1为克雷伯氏菌属,菌株CPY-4为地衣芽胞杆菌,菌株4和菌株13为肠杆菌属.     

外源水对碳酸盐侵蚀速率研究——以桂林毛村地下河为例

本文对桂林毛村地下河流域,进行了野外监测与室内分析研究,详细研究了外源水与岩溶水对碳酸盐岩侵蚀速率差异。研究结果表明,碳酸盐岩在岩溶水与外源水中的侵蚀速率存在较大差异,雨季碳酸盐岩侵蚀速率:外源水外源水补给的岩溶水岩溶水空气;旱季碳酸盐岩溶蚀速率:外源水外源水补给的岩溶水空气岩溶水;外源水中的灰岩侵蚀速率白云岩侵蚀速率;碳酸盐岩试块的侵蚀速率具有明显的季节变化,主要受控于方解石饱和指数、pH值与水动力条件。     

Photocatalytic Treatment of RDX Wastewater with Nano-Sized Titanium Dioxide (5 pp)

Background, Aim and Scope The polynitramines, hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX), octahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine (HMX), are important military explosives and regulated toxic hazardous compounds. Production, testing and use of the compounds has resulted in numerous acres of contaminated soils and groundwater near many munitions facilities. Economical and efficient methods for treatment of wastewater and cleanup of soils or groundwater containing RDX and HMX are needed. This study focuses on the photocatalytic treatment of RDX wastewater with nano-sized titanium dioxide (nano-TiO2) under simulated sunlight, whose intensity and wavelength are similar to that of the real sunlight in Xi'an at noon. The objective is to determine the potential for RDX destruction with nano-TiO2 in aqueous solution. Materials and Methods: An activated carbon fiber (ACF) cloth-loaded with nano-TiO2 was put into the RDX containing solution, and the concentration of RDX was measured (by HPLC–UV) at regular time intervals under simulated sunlight. Results: The RDX degradation percentage of the photocatalytic process is higher than that of Fenton oxidation before 80 min, equivalent after 80 min, and it reaches 95% or above after 120 min. The nano-TiO2 catalyst can be used repeatedly. Discussion: The photocatalytic degradation kinetics of RDX under simulated sunlight can be described by a first-order reaction kinetics equation. The possible degradation mechanism of RDX was presented and the degradation performance was compared with that of biological method. Conclusions: It was demonstrated that the degradation of RDX wastewater is very effective with nano-TiO2 as the photocatalytic catalyst under simulated sunlight. The efficiency of the nano-TiO2 catalyst for RDX degradation under simulated sunlight is nearly identical to that of Fenton oxidation. Recommendations and Perspectives: To date, a number of catalysts show poor absorption and utilization of sunlight, and still need ultraviolet light irradiation during wastewater degradation. The nano-TiO2 used in the described experiments features very good degradation of RDX under simulated sunlight, and the manufacturing costs are rather low (around 10 Euro/m2). Moreover, the degradation efficiency is higher compared to that of the biological method. This method exhibits great potential for practical applications owing to its easiness and low cost. If it can be applied extensively, the efficiency of wastewater treatment will be enhanced greatly.     

Pb(NO3)2与CPC共存对沉积物吸附对硝基苯酚的影响

选取Pb(NO3)2、氯化十六烷基吡啶(CPC)、对硝基苯酚为代表污染物,试验了重金属与表面活性剂共存对有机物在沉积物上吸附行为的影响.结果表明:Pb(NO3)2的存在减弱了CPC的增强吸附效应,Pb(NO3)2和CPC共存对对硝基苯酚的吸附产生拮抗效应.在固定CPC初始浓度不变的情况下,拮抗效应随Pb(NO3)2初始浓度增大而加强.同时,拮抗效应也取决于CPC的浓度.当CPC初始浓度小于3 000mg/L(平衡浓度低于临界胶束浓度CMC)时,这种拮抗效应尤为明显;随着表面活性剂浓度的继续增加,拮抗效应减弱,并逐渐趋向于CPC的独立效应机理探讨表明,共存体系中,Pb2 与CPC在同一吸附点位不存在竞争吸附.     

转盘式光催化燃料电池处理染料废水

采用阳极氧化法制备转盘式TiO_2阳极,设计并开发了转盘式光催化燃料电池(PFC),探讨了圆盘转速对PFC中染料降解效果的影响。实验结果表明:随着圆盘转速的提高,污染物和光电界面反应产物的传质作用得以强化,罗丹明B降解率提高;在圆盘转速为1 600 r/min、反应时间为60 min的条件下,罗丹明B降解率达90.8%,是圆盘转速为0 r/min时的8.5倍;光电流也随着圆盘转速的提高而提高,但提高幅度远小于罗丹明B降解率的提高幅度;同时,加强传质作用后再外加电压对PFC催化降解性能的提高作用有限。