微生物反向电渗析反应器产过氧化氢的研究

微生物反向电渗析(Microbial reverse-electrodialysis electrolysis cell, MREC)是一种通过微生物产生的电能与浓淡水盐差能耦合形成的一种新型的生物电化学技术.本文对MREC阴极回收H_2O_2的运行条件与影响因素及同步产能效应进行了研究.结果表明,浓淡水流速及浓度比是影响H_2O_2产生的关键因素.在浓淡水流速为2 mL·min~(-1)、浓/淡水比为100时,MREC可以获得最大H_2O_2产量711.4 mg·L~(-1),产H_2O_2速率达到最大33.65 mg·L~(-1)·h~(-1),阴极回收率为19.77%.同时,对应的产电性能达到1.25 W·m~(-2).MREC反应器能够在无需施加外界能源的情况下获得较高的H_2O_2产量,为H_2O_2绿色生产提供了一条新思路.     

SBR生物反应器出水溶解态有机物性质特点研究

研究中考察了SBR生物反应器处理实际生活污水过程中,反应器内部溶解性有机物的变化情况,重点分析了污泥龄对于SBR反应器出水溶解态有机物性质特点的影响.研究结果表明,生物降解过程中,以分子量650Da、1700Da和2000Da为代表的腐殖质类有机物逐渐积累,小分子量有机物(<200Da)逐渐转化为具有中间分子量(500...     

A simple approach to modeling microbial biomass in the rhizosphere

Microorganisms make an important contribution to the degradation of contaminants in bioremediation as well as in phytoremediation. An accurate estimation of microbial concentrations in the soil would be valuable in predicting contaminant dissipation during various bioremediation processes. A simple modeling approach to quantify the microbial biomass in the rhizosphere was developed in this study. Experiments were conducted using field column lysimeters planted with Eastern gamagrass. The microbial biomass concentrations from the rhizosphere soil, bulk soil, and unplanted soil were monitored for six months using an incubation–fumigation method. The proposed model was applied to the field microbial biomass data and good correlation between simulated and experimental data was achieved. The results indicate that plants increase microbial concentrations in the soil by providing root exudates as growth substrates for microorganisms. Since plant roots are initially small and do not produce large quantities of exudates when first seeded, the addition of exogenous substrates may be needed to increase initial microbial concentrations at the start of phytoremediation projects.     

实验条件下生态修复过程中微型生物群落演替研究

在实验室恒流－－修复微生态系统中，通过健康水体来对武汉东湖污染程度不同的水体进行持续替换，以模拟受不同程度污染胁迫的自然水体恢复过程，其间定期测定微型生物群落的中结构和功能参数，通过其变动机制和规律，再现修复过程中微型生物群落的演替过程，并从生态学角度提出了东湖5个受到不同程度污染水体得到修复的换水库。     

Pencycuron application to soils: degradation and effect on microbiological parameters

Clay loam soil from agricultural fields of alluvial (AL) soil (typic udifluvent) and coastal saline (CS) soil (typic endoaquept) were investigated for the degradation and effect of pencycuron application at field rate (FR), 2-times FR (2FR) and 10-times FR (10FR) with and without decomposed cow manure (DCM) on soil microbial variables under laboratory conditions. Pencycuron degraded faster in CS soil and in soil amended with DCM. Pencycuron spiking at FR and 2FR resulted in a short-lived (in case of 10FR slightly longer) and transitory toxic effect on soil microbial biomass-C (MBC), ergosterol content and fluorescein diacetate hydrolyzing activity (FDHA). Amendment of DCM did not seem to have any counteractive effect of the toxicity of pencycuron on the microbial variables. The ecophysiological status of the soil microbial communities as expressed by microbial metabolic quotient (qCO2) and microbial respiration quotient (Q(R)) changed, but for a short period, indicating pencycuron induced disturbance. The duration of this disturbance was slightly longer at 10FR. Pencycuron was more toxic to the metabolically activated soil microbial populations, specifically the fungi. It is concluded that side effects of pencycuron at 10FR on the microbial variables studied were only short-lived and probably of little ecological significance.     

铅与苄嘧磺隆复合污染对青紫泥微生物生物量的影响

通过实验室培养试验研究了铅(0、100、300、500、800 mg/kg)与苄嘧磺隆(0、5、10 mg/kg)单独及其复合污染对青紫泥田水稻土壤微生物生物量的影响.结果表明,两种污染物在整个培养过程中都对微生物生物量C、N产生了显著的抑制作用,其交互作用在各个取样时期也均达到了显著水平;在整个培养过程中微生物生物量C、N的含量表现出先降低后升高的变化趋势,在第7～14天下降到最低点;而对微生物生物量C/N比的影响则表现出先升高后下降的趋势.     

微生物光电化学池去除硝酸盐氮:以PANI/TiO2-NTs为光阳极

利用微生物光电化学池(MPEC)去除污染物是一种经济高效环保的方法.本实验在制备获得聚苯胺/二氧化钛纳米管阵列(PANI/TiO_2-NTs)复合光电极的基础上,构建了由PANI/TiO_2-NTs光阳极和生物阴极组成的MPEC系统,并对其去除硝酸盐氮(NO~-_3-N)的性能进行研究.结果表明,PANI负载时间为80 s时,PANI/TiO_2-NTs电极光电性能最佳,相比于TiO_2-NTs电极光电流密度增大约一倍,PANI的修饰有效提高了光能利用率.构建的MPEC系统能在无外加电压的条件下利用光能驱动实现自养反硝化脱氮,NO~-_3-N的生物降解符合准一级反应动力学方程.光响应电流密度越大,系统反硝化脱氮性能越好,NO~-_3-N初始浓度为25 mg·L~(-1)时,当光响应电流密度从0.17 mA·cm~(-2)增加至0.67 mA·cm~(-2),平均反硝化速率从0.83 mg·(L·h)~(-1)增大到2.83 mg·(L·h)~(-1).对生物阴极微生物膜进行了高通量测序,发现Pseudomonas所占比例最大(27.37%)为优势菌属.分析认为PANI/TiO_2-NTs光阳极产生的光生电子通过外电路传递到阴极,Pseudomonas、Alishewanella和Flavobacterium等具有自养反硝化能力和电化学活性的微生物可直接利用电极上的电子作为唯一的电子供体进行自养反硝化脱氮.     

喹啉和吡啶共存条件下的MFC产电特性研究

喹啉和吡啶往往共存于实际废水中,本文通过构双极室MFC,以铁氰化钾为电子受体,对喹啉和吡啶在MFC中的降解以及产电性进行研究.结果表明,MFC的最大输出电压随着葡萄糖浓度的降低而降低,当喹啉和吡啶初始浓度均为500mg·L-1,葡萄糖浓度分别为1000、500、100mg·L-1时,最高输出电压逐渐降低,分别为606、537、354mV;最大体积功率密度为18.4、14.4和6.3W.m-3.当以等浓度500mg·L-1的喹啉和吡啶作混合燃料时,MFC的内阻超过1250Ω,最大体积功率密度为2.9W.m-3.周期结束时,COD的去除率达79%以上,喹啉和吡啶均可以完全去除,喹啉的降解速率明显高于吡啶.MFC可以利用喹啉和吡啶作为混合燃料,这为含喹啉和吡啶共存类实际废水的MFC处理提供了理论依据.     

微生物燃料电池中产电微生物电子传递研究进展

微生物燃料电池集产电和污水净化为一体,作为一种新型的能源回收技术得到人们的广泛关注。从微生物燃料电池工作原理来看,电子能否顺利地传递到阳极表面对于电流的产生起着关键作用。因此,本文重点阐述了电子在产电微生物体内产生的途径、电子从微生物体内向阳极传递的不同方式以及阳极材料对产电微生物附着和电子传递的影响。从生物化学、电化学和材料学上对产电微生物体内的电子到阳极整个过程进行全面的综述。明确电子传递的关键环节,为新型高效阳极材料的开发提供思路。     

Volatile organic compound emissions from straw-amended agricultural soils and their relations to bacterial communities: A laboratory study

A laboratory study was conducted to investigate volatile organic compound(VOC) emissions from agricultural soil amended with wheat straw and their associations with bacterial communities for a period of 66 days under non-flooded and flooded conditions. The results indicated that ethene, propene, ethanol, i-propanol, 2-butanol, acetaldehyde, acetone,2-butanone, 2-pentanone and acetophenone were the 10 most abundant VOCs, making up over 90% of the total VOCs released under the two water conditions. The mean emission of total VOCs from the amended soils under the non-flooded condition(5924 ng C/(kg·hr)) was significantly higher than that under the flooded condition(2211 ng C/(kg·hr)). One "peak emission window" appeared at days 0–44 or 4–44, and over 95% of the VOC emissions occurred during the first month under the two water conditions. Bacterial community analysis using denaturing gradient gel electrophoresis(DGGE) showed that a relative increase of Actinobacteria, Bacteroidetes, Firmicutes and γ-Proteobacteria but a relative decrease of Acidobacteria with time were observed after straw amendments under the two water conditions. Cluster analysis revealed that the soil bacterial communities changed greatly with incubation time, which was in line with the variation of the VOC emissions over the experimental period. Most of the above top 10 VOCs correlated positively with the predominant bacterial species of Bacteroidetes, Firmicutes and Verrucomicrobia but correlated negatively with the dominant bacterial species of Actinobacteria under the two water conditions. These results suggested that bacterial communities might play an important role in VOC emissions from straw-amended agricultural soils.