城市污水处理厂内分泌干扰物浓度分布和去除规律

采集南方某城市3个污水处理厂进出水及各工艺单元的水样,通过固相萃取-衍生化过程对水样进行预处理,并用气相色谱-质谱联用仪定量检测水样中的17α-雌二醇(17α-E2)、雌酮(E1)、雌二醇(E2)、雌炔醇(EE2)、雌三醇(E3)、辛基酚(OP)、正壬基酚(NP)和双酚A(BPA)等8种内分泌干扰物(EDCs).连续4个季度的分析结果显示,3个污水厂进出水及各工艺单元中均有EDCs检出,EE2和BPA是含量最高的两种EDCs,出水中最高浓度分别达到498.9ng.L-1和2652.5ng.L-1,其他6种EDCs浓度均不超过100ng.L-1;生物处理工艺对EE2、E3、NP、OP和BPA有较高的去除率,平均去除率约为57%～85%,但对于E1、E2和17α-E2的去除率较低且不稳定;一级处理工艺对EDCs仅有低于18%的去除率;紫外辐照消毒工艺对EDCs的去除没有明显效果;EDCs浓度季节差异显著,由于雨水的稀释作用,旱季浓度约为雨季的2.5～7.8倍.本文对于了解我国南方地区污水处理工艺中EDCs类物质的分布和转化特点有一定的参考意义.     

Biodegradation of N,N-bis(carboxymethyl)-L-glutamate and its utilization as sole source of carbon,nitrogen, and energy by a Rhizobium radiobacter strain in seawater

Biodegradation of N,N-bis(carboxymethyl)-L-glutamate and its utilization by micro-organisms in marine environments were studied in Organization of Economic Development and Cooperation (OECD) screening tests and with pure bacterial cultures. Biodegradation in excess of 60% was achieved in closed bottle tests in less than 60 days, suggesting complete degradation. The bacterial strain isolated from marine sandy sediment and utilizing N,N-bis(carboxymethyl)-L-glutamate as sole source of carbon, nitrogen, and energy was identified as Rhizobium radiobacter. The strain was capable to mineralize N,N-bis(carboxymethyl)-L-glutamate in seawater and in synthetic media containing 0–60 g L^?1 sea salts. Growth and adaptation studies indicated that N-carboxymethyl-L-glutamate and L-glutamate are main metabolites.     

甲苯降解菌的分离、鉴定及其对甲苯的降解特性

从重庆钢铁集团焦化厂脱酚池车间污泥中分离纯化得到一株能以甲苯为惟一碳源和能源的革兰氏阴性菌。根据生理生化实验结果、菌落特征、菌体形态,初步鉴定为假单孢菌属。菌株的最佳生长条件为：pH7、温度35℃、加入量100mL培养基中加入60μL甲苯、接种量5．0％。考察了菌株对甲苯的降解特性,在甲苯质量浓度为150mg/L时,比降解速率达到0．211h^-1。     

光催化与生物膜直接耦合降解4-氟苯酚废水

为了实现4-氟苯酚(4-FP)废水的快速持续降解,本文构建了光催化与生物膜直接耦合系统.该耦合系统由N掺杂TiO2涂覆光催化光纤束、生物膜、核孔膜和紫外-可见LED光源构成.实验研究了单独光催化、单独微藻生物膜及光催化-生物膜耦合3种体系对4-FP的降解性能.研究发现:光催化系统降解4-FP速率慢、脱氟效率低,12h内...     

钻井液化学剂可生物降解性评定方法

介绍研究钻井液化学剂生物降解性的必要性及开发可生物降解钻井液的进展。阐述了常用的评定有机物生物降解性的试验方法。推荐采用BOD_5／COD_Cr比值来评定我国石油行业钻井液化学剂及油田化学剂的可生物降解性，规范石油行业生物降解研究工作，保证评定结果的可靠性和可比性。     

水势与用氮量对土壤中石油降解的影响

研究了石油降解过程中，土壤有效氮的动态变化，不同用氮水平在两种土壤上对石油降解速率的影响，以及石油降解的土壤水势条件。结果表明，石油对土壤的污染没有影响土壤水势；在土壤水势为－１００～－２０ｋＰａ范围内，水势的降低没有影响石油分解，而当土壤水势为－１０００ｋＰａ时，石油降解速率与对照相比下降了１０％～３５％。在壤土上，肥料氮添加在碳（石油中碳）氮（肥料中氮）比为９０时，石油降解最快；过多施用肥料氮会降低石油的分解速率。     

城市垃圾填埋场的沉降研究

通过对位于上海老港填埋场的3000 m2试验场(垃圾填埋高度4 m,填入垃圾10800 t)历时880 d的沉降监测,根据垃圾在填埋场中的降解机理,建立了反映填埋场沉降规律的数学模型,证明了模型的可靠性。研究表明,填埋场的第二阶段沉降(由于垃圾的生物降解而产生的)与填埋时间的指数呈线性关系。根据沉降规律,上海老港填埋场完成大约79%的第二阶段沉降,才能处于高稳定化状态。     

Impact of solids on biphasic biodegradation of phenanthrene in the presence of hydroxypropyl- β -cyclodextrin (HPCD)

The consequence of polycyclic aromatic hydrocarbons (PAHs) in the environment is of great concern. The hydrophobic properties of PAHs significantly impact phase distribution causing limited bioavailability. Enhanced biodegradation has been extensively carried out by surfactants and the redeployment effect was recognized. However, the quantitative relationship concerning the impact of solids was rarely reported. A batch of biphasic tests were carried out by introducing Mycobacterium vanbaalenii PYR-1 and hydroxypropyl-β-cyclodextrin (HPCD) into a mixture of phenanthrene solution and various glass beads (GB37-63, GB105-125, and GB350-500). The comparative results demonstrated that HPCD had little effect on microbial growth and was not degradable by bacterium. A model was proposed to describe the biodegradation process. The regression results indicated that the partition coefficient k_d (1.234, 0.726 and 0.448 L·g⁻¹) and the degradation rate k (0 mmol·L⁻¹: 0.055, 0.094, and 0.112; 20 mmol·L⁻¹: 0.126, 0.141, and 0.156; 40 mmol·L⁻¹: 0.141, 0.156 and 0.184 d⁻¹) were positively and negatively correlated with the calculated total surface area (TSA) of solids, respectively. Degradation enhanced in the presence of HPCD, and the enhancing factor f was calculated (20 mmol·L⁻¹: 15.16, 40.01, and 145.5; 40 mmol·L⁻¹: 13.29, 37.97, and 138.4), indicating that the impact of solids was significant for the enhancement of biodegradation.     

Microbial biomass yield and turnover in soil biodegradation tests: carbon substrate effects

Most of the standardized biodegradation tests used to assess the ultimate biodegradation of environmentally degradable polymers are based solely on the determination of net evolved carbon dioxide. However, under aerobic conditions, it has to be considered that heterotrophic microbial consortia metabolize carbon substrates both to carbon dioxide and in the production of new cell biomass. It is generally accepted that in the relatively short term, 50% of the carbon content of most organic substrates is converted to CO₂, with the remaining carbon being assimilated as biomass or incorporated into humus. The latter is particularly important when the metabolism of the organic matter occurs in a soil environment. A straightforward relationship between the free-energy content of a carbon substrate (expressed as the standard free-energy of combustion) and its propensity for conversion to new microbial biomass rather than mineralization to CO₂ has been established. This can potentially lead to underestimation of biodegradation levels of test compounds, especially when they consist of carbon in a fairly low formal oxidation state and relatively high free-energy content. In the present work, the metabolism of different kind of carbon substrates, especially in soil, is reviewed and compared with our own experimental results from respirometric tests. The results show that conversion of highly oxidized materials, such as the commonly used reference materials, cellulose or starch, to CO₂ may be significantly overestimated. The addition of glucosidic material to soil leads to greatly increased respiration and is accompanied by a very low conversion to biomass or humic substances. In contrast, relatively less oxidized substrates metabolize more slowly to give both CO₂ and biomass to an extent which may be significantly underestimated if glucosidic materials are used as the reference. The need for an overall carbon balance taking into account both the carbon immobilized as biomass and that volatized as CO₂ must be considered in standard respirometric procedures for assessing the biodegradability of slowly degrading macromolecules.     

Biological degradation of some organic compounds involved in the paper industry

An evaluation of the biodegradation by aerobic microorganisms was investigated for some organic compounds occurring in paper manufacturing technology. Lines of biodegradation for nine organic compounds, as a percentage removal of chemical oxygen demand (COD), were detected over seven days incubation. The results of the biodegradability test clearly revealed that some of the organic compounds under investigation were highly biodegradable while others ranked from fairly biodegradable to non-biodegradable. Significant biodegradation results were recorded as COD removal, for anti-coating ester (95.0 percent), Basoplast 200D (85.3 percent) and Basoplast PR 8050 (87.6 percent). The bleaching agent (formamidin-sulfinic acid), Ukanol BSA and Solidurit KM demonstrated moderate biodegradation with results of 62.1 percent, 76.2 percent and 69.8 percent, respectively. Poor biodegradation results for Hedifix M/35 (12.7 percent), Basazol Orange (34.9 percent) and Basazol Brown (29.0 percent) were recorded. Accordingly, appropriate precautions should be taken into consideration when applying these compounds to paper manufacturing processes.