双室MFC同时处理活性污泥及氨氮废水的研究

为了探究双室微生物燃料电池同时处理活性污泥及氨氮废水的性能及机理,利用微生物燃料电池阳极室处理活性污泥,阴极室处理氨氮废水。分析了阳极室不同灭菌与未灭菌污泥的添加比例,阴极室是否接种硝化菌及不同氨氮初始浓度下微生物燃料电池的产电特性,通过各反应器的电流密度、功率密度及极化曲线变化来分析微生物燃料电池的最佳运行条件。通过化学需氧量(COD)、氨氮、微生物群落差异化分析微生物燃料电池处理活性污泥及氨氮废水的性能。结果表明:微生物燃料电池在阳极灭菌污泥与未灭菌污泥比例为1∶10时,阳极室COD去除率均达到80%以上,此时阴极室接种硝化菌且氨氮初始浓度为50 mg/L的条件下产电效果最好,获得电流密度峰值为366.38 m A/m~2,且峰值持续时间最长;当阴极接种硝化菌时,不同的阴阳极室条件下阴极室氨氮都可以完全去除。     

光合微生物燃料电池处理餐厨沼液的性能研究

采用小球藻作为双室光合藻微生物燃料电池（PAMFC）的阴极以提供电子受体,实现污水处理和能量回收的双重目的.研究生物阴极接种方式和光照条件对生物产电性能和餐厨沼液废水处理效果的影响,并通过循环伏安法（CV）研究PAMFC电极极化和产电机制.结果表明：微藻生物膜阴极PAMFC污染物去除和产电性能表现优于对照组,COD,TN和TP去除率最高可达82.4%,54.5%和82.3%,开路电压和最大功率密度分别达603.0mV和41.5mW/m².污染物去除主要在阳极发生,但阴极能够还原去除来自阳极的铵根离子,且阴极反应产生氧气作为阳极的电子受体,增大系统电流,提高了阳极处理效率.持续光照下,PAMFC产电性能和污染物去除率略高于间歇光照,但是间歇光照可以避免阳极基质不足时阴极光饱和和氧饱和情况,更符合连续运行要求.PAMFC阴极的CV曲线显示,具有微藻阴极的实验组输出电压更大,还原峰更高,功率密度更强,但需注意长期运行时微藻生物膜增厚影响氧传质效率的问题.     

光合微生物燃料电池处理餐厨沼液的性能研究

采用小球藻作为双室光合藻微生物燃料电池（PAMFC）的阴极以提供电子受体,实现污水处理和能量回收的双重目的.研究生物阴极接种方式和光照条件对生物产电性能和餐厨沼液废水处理效果的影响,并通过循环伏安法（CV）研究PAMFC电极极化和产电机制.结果表明：微藻生物膜阴极PAMFC污染物去除和产电性能表现优于对照组,COD,TN和TP去除率最高可达82.4%,54.5%和82.3%,开路电压和最大功率密度分别达603.0mV和41.5mW/m².污染物去除主要在阳极发生,但阴极能够还原去除来自阳极的铵根离子,且阴极反应产生氧气作为阳极的电子受体,增大系统电流,提高了阳极处理效率.持续光照下,PAMFC产电性能和污染物去除率略高于间歇光照,但是间歇光照可以避免阳极基质不足时阴极光饱和和氧饱和情况,更符合连续运行要求.PAMFC阴极的CV曲线显示,具有微藻阴极的实验组输出电压更大,还原峰更高,功率密度更强,但需注意长期运行时微藻生物膜增厚影响氧传质效率的问题.     

双室微生物燃料电池处含银废水的产电性研究

以剩余污泥为阳极底,糖蜜废水为基质,Ag Cl废水为阴极电子受体,构建了双室微生物燃料电池(Two-chamber Microbial Fuel Cell,简称MFCs),并研究了电池的产电特性、库仑效率及金属去除率.结果表明:Ag+不仅可以作为阴极电子受体,而且还能稳定产电,外电阻为1000Ω时,获得的最大电压为514.5 m V,最大功率密度为65.82 m W·m-2.在阴极实现了对废水中Ag+的去除,最大去除率可达71.6%,而且Ag+浓度为2000 mg·L-1时,回收金属银单质质量为197.66 g.在阳极对废水的处理效果也很显著,库仑效率最高为2.66%,COD去除率最大为81.22%.     

单室微生物燃料电池产电与脱氮除磷的研究

实验针对空气阴极型单室微生物燃料电池(Microbial Fuel Cell,MFC),研究其产电性能及对实验室模拟废水中有机物、氮和磷元素的去除效果.结果表明,在外电阻为1000Ω的情况下,该电池最大输出电压可达371 m V,最大输出功率密度可达301.6 m W·m~(-2),最大电流密度可达2.4 A·m~(-2),内阻为200Ω.当入水氨氮浓度为4 mmol·L~(-1)时,该电池的产电效果最好,对污染物的去除效果也较好.研究还发现,电池最佳运行周期为72 h,阳极室出水最佳曝气时间为6 h,阳极室出水COD、TN和TP的降解率分别为93.3%、19.7%和44.8%.将阳极液曝气处理后,相对于阳极室入水其TN和TP的总去除率分别可达79.6%和95.2%.另外,通过扫描电镜观察到MFC的阳极液中大多为球形菌,阴极电极表面有针状的结晶形成,经能谱测试为鸟粪石结晶.     

漆酶包埋修饰阴极提高生物-电-芬顿处理聚醚废水处理效率

利用漆酶包埋修饰碳毡阴极构建微生物燃料电池-电-芬顿体系强化降解聚醚废水.结果表明,在pH为4,漆酶浓度为7 mg·mL~(-1)时,24 h后阴极室聚醚废水COD降解率达68.1%,比未修饰的碳毡阴极提高28%.漆酶修饰阴极强化电池的产电性能和提高H_2O_2的浓度,且H_2O_2的浓度在此工艺中起关键作用.微生物燃料电池最大电压达548 mV,H_2O_2最大浓度为3.14 mg·L~(-1),分别比碳毡阴极提高21.8%和25.6%.从三维荧光谱图中得出聚醚废水中的双酚和甲苯二胺等荧光物质被降解.综上所述,漆酶包埋修饰阴极是提高MFC-electro-Fenton处理聚醚废水效率的有效途径.     

阳极材料对6 L微生物燃料电池性能及有机废水处理效果的影响

阳极材料是影响微生物燃料电池实用化的关键因素之一.本文以碳刷、碳布或石墨毡阳极和泡沫镍空气阴极制成紧凑式6 L单室双空气阴极微生物燃料电池(MFC),研究不同阳极材料对电池启动过程和运行以乙酸钠为基质的人工废水和实际屠宰废水的产电性能和废水处理效果的影响,比较了单位阳极成本的产电效益.结果表明:阳极材料对紧凑式MFC的启动过程没有明显影响;在产电性能方面,碳刷阳极MFC在人工废水和屠宰废水中的输出功率密度最高,分别为(56.3±1.8)W·m~(-3)和(19.5±0.8)W·m~(-3),其次为碳布阳极MFC,分别为(46.0±1.7)W·m~(-3)和(16.9±0.6)W·m~(-3),最差的是石墨毡阳极MFC,分别为(40.8±1.5)W·m~(-3)和(11.9±0.5)W·m~(-3);在废水处理效果方面,不同阳极MFC在运行人工废水或屠宰废水时COD去除率没有明显差别,均在90%左右.碳刷阳极MFC所产生的经济效益最高,在运行乙酸钠和屠宰废水时分别为(3.44±0.08)m W·元-1和(0.97±0.05)m W·元-1,分别比碳布MFC和石墨毡MFC高18.6%、12.8%和38.7%、80%.本研究结果说明碳刷是微生物燃料电池实用化过程中最合适的阳极材料.     

利用双室微生物燃料电池处理模拟废水的产电特性研究

本实验通过研究电池的启动过程、阳极有机物降解率和阴极Cu2+的去除率,评价了微生物燃料电池(microbial fuel cell,MFC)的产电和处理废水性能.以模拟糖蜜废水作为阳极基质,模拟电镀废水作阴极电子受体,建立简单的双室微生物燃料电池.结果表明在外电阻为800Ω的情况下,电池得到最大电压417.00 mV,从极化曲线上获得最大输出功率密度44.17mW.m-2,内阻为293Ω.电池在第五周期时,COD去除率也达到最高47.31%.在第四周期内,Cu2+最大的去除率为59.76%.综上所述,MFC在处理有机废水和电镀废水方面具有可行性.     

耐高氨氮异养硝化-好氧反硝化菌TN-14的鉴定及其脱氮性能

从环境中筛选出1株耐高氨氮、具有产絮、异养硝化-好氧反硝化能力的新菌株TN-14,对其进行生理生化特征及分子鉴定、异养硝化-好氧反硝化能力以及产絮性能的考察,并研究其与耐氨氮能力以及对高氨氮猪场废水的除污性能.根据菌株生理生化特征以及分子鉴定结果,可初步确定菌株TN-14为不动杆菌Acinetobacter sp..异养硝化反应体系中,24 h内菌株TN-14对氨氮、总氮的去除率分别达到97.13%和93.53%;硝酸盐反硝化体系中,24 h内硝态氮从94.24 mg·L-1降到39.32mg·L-1,硝态氮的去除率达到58.28%,反硝化速率为2.28 mg·(L·h)-1;亚硝酸盐反硝化体系中,亚硝态氮从反应初始浓度97.78 mg·L-1下降到21.30 mg·L-1,亚硝态氮去除率达78.22%,反硝化速率为2.55 mg·(L·h)-1.菌株TN-14具有良好的产絮特性,其培养液对0.4%的高岭土悬浊液的絮凝率可达94.74%;菌株TN-14能够在氨氮高达1200 mg·L-1的环境下生长.菌株TN-14对实际猪场废水中的COD、氨氮、总氮和总磷去除率分别达到85.30%、65.72%、64.86%和79.41%,在实际高氨废水生物处理中具有良好的应用前景.     

双筒型微生物燃料电池产电及污水净化特性的研究

构建了双筒型微生物燃料电池并考察了产电和污水净化特性,在此基础上考察不同阳极填料对微生物燃料电池产电的影响.通过稳态放电法和电流中断法测量得到微生物燃料电池的内阻,以颗粒石墨作为阳极填料的双筒型微生物燃料电池内阻为38.9 Ω,阳极内阻、欧姆内阻和阴极内阻分别为5.1、 14.1和18.7 Ω,最大产电功率密度为6 253　mW/m³,双筒型微生物燃料电池的构型能有效提高单位体积质子膜面积.双筒型微生物燃料电池对COD的去除负荷为1.6 kg/(m³·d),库仑效率约为10%～12%.阳极填料为大颗粒石墨、小颗粒石墨、碳毡和穿孔型碳毡的双筒型微生物燃料电池的内阻分别为47、 39、 28和33 Ω,稳定运行周期分别为20、 18、 11和18 d.从兼顾产电和稳定运行角度出发,穿孔型碳毡和小颗粒石墨更适合用作MFC阳极填料.     

Toxic effects of acetochlor, methamidophos and their combination on nifH gene in soil

Toxic effects of two agrochemicals on nifH gene in agricultural black soil were investigated using denaturing gradient gel electrophoresis （DGGE） and sequencing approaches in a microcosm experiment. Changes of soil nifH gene diversity and composition were examined following the application of acetochlor, methamidophos and their combination. Acetochlor reduced the nifH gene diversity （both in gene richness and diversity index values） and caused changes in the nifH gene composition. The effects of acetochlor on nifH gene were strengthened as the concentration of acetochlor increased. Cluster analysis of DGGE banding patterns showed that nifH gene composition which had been affected by low concentration of acetochlor （50 mg/kg） recovered firstly. Methamidophos reduced nifH gene richness that except at 4 weeks. The medium concentration of methamidophos （150 mg/kg） caused the most apparent changes in nifH gene diversity at the first week while the high concentration of methamidophos （250 mg/kg） produced prominent effects on nifH gene diversity in the following weeks. Cluster analysis showed that minimal changes of nifH gene composition were found at 1 week and maximal changes at 4 weeks. Toxic effects of acetochlor and methamidophos combination on nifH gene were also apparent. Different nifH genes （bands） responded differently to the impact of agrochemicals： four individual bands were eliminated by the application of the agrochemicals, five bands became predominant by the stimulation of the agrochemicals, and four bands showed strong resistance to the influence of the agrochemicals. Fifteen prominent bands were partially sequenced, yielding 15 different nifH sequences, which were used for phylogenetic reconstructions. All sequences were affiliated with the alpha- and beta-proteobacteria, showing higher similarity to eight different diazotrophic genera.     

EDTA-enhanced phytoremediation of lead contaminated soil by Bidens maximowicziana

Phytoremediation is a potential cleanup technology for the removal of heavy metals from contaminated soils.Bidens maximowicziana is a new Pb hyperaccumulator,which not only has remarkable tolerance to Pb but also extraordinary accumulation capacity for Pb.The maximum Pb concentration was 1509.3 mg/kg in roots and 2164.7 mg/kg in overground tissues.The Pb distribution order in the B. maximowicziana was:leaf>stem>root.The effect of amendments on phytoremediation was also studied.The mobility of soil Pb and the Pb concentrations in plants were both increased by EDTA application.Compared with CK(control check),EDTA application promoted translocation of Pb to overground parts of the plant.The Pb concentrations in overground parts of plants was increased from 24.23-680.56 mg/kg to 29.07-1905.57 mg/kg.This research demonstrated that B.maximowicziana appeared to be suitable for phytoremediation of Pb contaminated soil,especially,combination with EDTA.     

Distribution and ecological effect of mercury in Laogang landfill, Shanghai, China

Laogang landfill near Shanghai is the largest landfill in China, and receives about 10000 t of daily garbage per day, Samples of topsoil and plants were analyzed to evaluate mercury pollution from the landfill. For topsoil samples, there were significant correlations among total mercury （HgT）, combinative mercury （Hgc） and gaseous mercury （HgG）, and content of total organic carbon （TOC）, but, no significantly relationship was found between Hg content and filling time. Hg content changes in vertical profiles with time showed that the average Hgv of profiles 1992, 1996, and 2000 was similar, but their average HgG was quite different. HgT was significantly correlated with Hgc in profile 1992 and 2000, and Hgv was significantly correlated with Hg6 in profile 1996. HgG/Hgv ratio in profile samples decreased in the order of （HgG,/HgT）1992〉（HgG/HgT）1996〉〉（HgG/HgT）2000. A simple outline of Hg release in landfill could be drawn： with increasing of filling time, degradation undergoes different biodegradation, accordingly, gaseous mercury goes through small, more, and small proportion to total mercury. Distribution of Hg in plants was inhomogeneous, following the order of leaf〉root〉stem. The highest value of leaf may be associated with higher atmospheric Hg from landfill. Ligneous plants （e.g. Phyllostachys glanca, Prunus salicina and Ligustrum lucidum） are capable of enriching more Hg than herbaceous plants.     

Arsenic uptake by arbuscular mycorrhizal maize （Zea mays L.） grown in an arsenic-contaminated soil with added phosphorus

The effects of arbuscular mycorrhizal (AM) fungus (Glomus mosseae) and phosphorus (P) addition (100 mg/kg soil) on arsenic (As) uptake by maize plants (Zea mays L.) from an As-contaminated soil were examined in a glasshouse experiment.Non-mycorrhizal and zero-P addition controls were included.Plant biomass and concentrations and uptake of As,P,and other nutrients,AM colonization,root lengths,and hyphal length densities were determined.The results indicated that addition of P significantly inhibited root colonization and development of extraradical mycelium.Root length and dry weight both increased markedly with mycorrhizal colonization under the zero-P treatments,but shoot and root biomass of AM plants was depressed by P application.AM fungal inoculation decreased shoot As concentrations when no P was added,and shoot and root As concentrations of AM plants increased 2.6 and 1.4 times with P addition,respectively.Shoot and root uptake of P,Mn,Cu,and Zn increased,but shoot Fe uptake decreased by 44.6%,with inoculation, when P was added.P addition reduced shoot P,Fe,Mn,Cu,and Zn uptake of AM plants,but increased root Fe and Mn uptake of the nonmycorrhizal ones.AM colonization therefore appeared to enhance plant tolerance to As in low P soil,and have some potential for the phytostabilization of As-contaminated soil,however,P application may introduce additional environmental risk by increasing soil As mobility.     

Enzymatic oxidation of aqueous pentachlorophenol

The influence of the nonionic surfactant Tween 80 on pentachlorophenol （PCP） oxidation catalyzed by horseradish peroxidase was studied. The surfactant was tested at concentrations below and above its critical micelle concentration （CMC）. Enhancement of PCP removal was observed at sub-CMCs. The presence of Tween 80 in the reaction mixture reduced enzyme inactivation which occurred through a combination of free radical attack and sorption by precipitated products. A simple first-order model was able to simulate time profiles for enzyme inactivation in the presence or absence of Tween 80. At supra-CMCs, the surfactant caused noticeable reductions in PCP removal, presumably through micelle partitioning of PCP which precluded the hydrophobic PCP molecule from interacting with the enzyme.     

Decomposition of alachlor by ozonation and its mechanism

Decomposition and corresponding mechanism of alachlor, an endocrine disruptor in water by ozonation were investigated. Results showed that alachlor could not be completely mineralized by ozone alone. Many intermediates and final products were formed during the process, including aromatic compounds, aliphatic carboxylic acids, and inorganic ions. In evoluting these products, some of them with weak polarity were qualitatively identified by GC-MS. The information of inorganic ions suggested that the dechlorination was the first and the fastest step in the ozonation of alachlor.     

Degradation of metabolites accumulated of benzo[a]pyrene by coupling Penicillium Chrysogenum with KMnO4

Several main metabolites of benzo[a]pyrene （BaP） formed by Penicillium chrysogenum, Benzo[a]pyrene-1,6-quinone （BP 1,6- quinone）, trans-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene （BP 7,8-diol）, 3-hydroxybenzo[a]pyrene （3-OHBP）, were identified by high-performance liquid chromatography （HPLC）. The three metabolites were liable to be accumulated and were hardly further metabolized because of their toxicity to microorganisms. However, their further degradation was essential for the complete degradation of BaP. To enhance their degradation, two methods, degradation by coupling Penicillium chrysogenum with KMnO4 and degradation only by Penicillium chrysogenum, were compared; Meanwhile, the parameters of degradation in the superior method were optimized. The results showed that （1） the method of coupling Penicillium chrysogenum with KMnO4 was better and was the first method to be used in the degradation of BaP and its metabolites; （2） the metabolite, BP 1,6-quinone was the most liable to be accumulated in pure cultures; （3） the effect of degradation was the best when the concentration of KMnO4 in the cultures was 0.01% （w/v）, concentration of the three compounds was 5 mg/L and pH was 6.2. Based on the experimental results, a novel concept with regard to the bioremediation of BaP-contaminated environment was discussed, considering the influence on environmental toxicity of the accumulated metabolites.     

Impact of atrazine and nitrogen fertilizers on the sorption of chlorotoluron in soil and model sorbents

Sorption of chlorotoluron in ammonium sulfate, urea and atrazine multi-solutes system was investigated by batch experiments. The results showed application of nitrogen fertilizers to the soil could affect the behavior of chlorotoluron. At the same concentration of N, sorption of chlorotoluron decreased as the concentration of atrazine increased on the day 0 and 6 in soil, respectively. The sorption of chlorotoluron increased from 0 to 6 d when soils were preincubated with deionized water, ammonium sulfate and urea solution for 6 d. That indicated incubation time was one of the most important factors for the sorption of chlorotoluron in nitrogen fertilizers treatments. The individual sorption isotherms of chlorotoluron in rubbery polymer and silica were strictly linear in single solute system, but there were competition sorption between pesticides or between pesticides and nitrogen fertilizers. That indicated the sorption taken place by concurrent solid-phase dissolution mechanism and sorption on the interface of water-organic matter or water-mineral matter.     

基于综合水质标识指数和对应分析法的校园河道水质评价

以三峡大学的校园河道求索溪为研究对象,利用综合水质标识指数法确定求索溪水质类别,分析其水质时空变化规律,并利用对应分析法得出求索溪中不同监测点的主要污染因子.研究结果表明:求索溪整体的综合水质标识指数为7.423,整体水质为劣V类(地表水环境质量标准GB 3838-2002)且黑臭.从时间变化来看,求索溪4月份的水质最差,5月份次之,4、5月份所有监测点的水质都劣于V类且黑臭;8月份水质最好,水质为Ⅳ类;从空间分布来看,8个监测点综合水质标识指数均超过6.0,水质为劣V类,其中6号监测点的水质相对最好,监测点3号的水质相对最差;对应分析法得出求索溪的整体水体污染程度受总氮因子的影响最大,其次为总磷.该研究拟为求索溪及类似校园河道的水环境治理研究提供基础依据和参考.     

Potential of plant polyphenol oxidases in the decolorization and removal of textile and non-textile dyes

In this study an effort has been made to use plant polyphenol oxidases; potato （Solanum tuberosum） and brinjal （Solanum melongena）, for the treatment of various important dyes used in textile and other industries. The ammonium sulphate fractionated enzyme preparations were used to treat a number of dyes under various experimental conditions. Majority of the treated dyes were maximally decolorized at pH 3.0. Some of the dyes were quickly decolorized whereas others were marginally decolorized. The initial first hour was sufficient for the maximum decolorization of dyes. The rate of decolorization was quite slow on long treatment of dyes. Enhancement in the dye decolorization was noticed on increasing the concentration of enzymes. The complex mixtures of dyes were treated with both preparations of polyphenol oxidases in the buffers of varying pH values. Potato polyphenol oxidase was significantly more effective in decolorizing the dyes to higher extent as compared to the enzyme obtained from brinjal polyphenol oxidase. Decolorization of dyes and their mixtures, followed by the formation of an insoluble precipitate, which could be easily removed simply by centrifugation.