好氧微生物在硝基苯污染河水原位修复中的应用

在好氧条件下,从长期受硝基苯污染的化工厂排污口底泥和河道底质中分离得到3株对硝基苯有明显降解作用的优势微生物.为了比较这些优势菌的降解效果,作了硝基苯初始质量浓度分别为50 mg/L、25 mg/L、12.5 mg/L、6.25 mg/L、3.13 mg/L等不同梯度下的模拟修复实验,并且检验了单一菌与混合菌的降解能力.实验结果表明:当硝基苯初始质量浓度为50 mg/L时,优势菌作用不明显,硝基苯的去除主要依靠自然挥发作用;当硝基苯初始质量浓度为3.13 mg/L时,混合菌对硝基苯的降解能力较强,72 h的去除率达到99%,而此时空白对照(CK)的去除率仅为60%.分析实验结果得到,混合菌可能存在协同作用;由于产物中未检出NO2-,所以硝基苯降解途径中可能存在部分还原历程.     

海岸带含水层咸淡水界面随潮汐波动的数值模拟

在分析、研究了滨海地带含水层和不透水层的水文地质特性及含水层内的咸淡水渗流运动特征的基础上,运用数学推理的手法,建立了一种较为简单适用的模拟海岸带含水层咸淡水界面和天然地下水面变动规律的二维数学模型,通过该模型的计算值与实验值的比较,证明该模型的计算结果与实验结果有着非常好的拟合度,即该模型能较客观地揭示海水入侵引起的咸淡水界面的变化规律.其后,运用该模型系统的探讨了含水层以下为非平坦的不透水层的滨海地带天然地下水面、咸淡水界面伴随着潮汐的波动而变化的规律.即伴随着潮汐的波动,一方面天然地下水面和咸淡水界面与潮汐具有相似的振动波形,波动的幅度随离海岸距离的增加而减小.在海岸附近咸淡水界面的振幅大于天然地下水面的振幅,而在离开海岸一定距离后天然地下水面的振幅超过咸淡水界面的振幅.总体上天然地下水面的振幅呈负指数衰减,而咸淡水界面的振幅几乎呈直线衰减(其衰减直线的倾角在135～150 °之间变动),且潮汐波动对天然地下水面影响的范围远大于其对咸淡水界面的影响;另一方面天然地下水面和咸淡水界面波动的振幅及它们之间的相位差的大小还与天然地下水面的水力坡度、含水层的渗透系数、有效孔隙率、不透水层形状及其变动的幅度有关,但它们之间的相位差的大小与潮汐波动的幅度无关,其振幅与潮汐的振幅成比例增减.当不透水层的形状一定时,不论天然地下水面的水力坡度、含水层的渗透系数、有效孔隙率及潮汐波动的幅度怎么变动,天然地下水面、咸淡水界面振动的相位差的变化趋势及其峰值出现的位置几乎不变,即不透水层的形状决定着天然地下水面、咸淡水界面振动的相位差的变化趋势,而其大小与含水层的水文地质参数(水力坡度、渗透系数及有效孔隙率)密切相关.此外,当天然地下水面和咸淡水界面的振动存在相位和振幅的较大差异时,可以断定含水层以下存在非平坦的不透水层,且这种差异越大,不透水层凸凹不平的程度越高.     

三阶段温度控制堆肥接种法对有机氮变化规律的影响

利用原生生活垃圾,通过三阶段温度控制技术进行堆肥试验,探讨在堆肥过程中有机态氮组分的动态变化规律.结果表明,全氮、酸水解有机态氮、氨基酸态氮均在堆肥的前期呈明显的下降趋势,呈较好的相关性.与CK（对照组）处理相比,在堆肥的后期,三阶段温度控制堆肥酸水解有机态氮、氨基酸态氮、氨基糖态氮及酸解未知态氮含量呈不同程度的上升趋势,增加幅度依次为：10.67%、16.17%、7.17%、22.44%.表明三阶段温度控制技术能减少堆肥中氮素的损失,堆肥产品施入土壤后,可提高土壤的供氮潜力.     

微生物对土壤与沉积物吸附多环芳烃的影响

以枯草芽孢杆菌为接种微生物,研究微生物对沉积物和湿地土壤吸附多环芳烃（PAHs）菲、苯并［a］芘过程的影响.结果表明,枯草芽孢杆菌对菲与苯并［a］芘都可进行吸附或生物降解,48h液相PAHs浓度达到平衡时,微生物对菲消除了98％,对苯并［a］芘消除85％;接种的样品48h吸附等温线均呈线形,能较好地符合线性方程;在接种微生物情况下,沉积物与土壤对菲和苯并［a］芘吸附特征均发生较大变化,对菲的吸附量增大约35倍,而对苯并［a］芘的吸附量却降低了2/3左右;未接种微生物的土壤和沉积物对菲解吸率为20％,接种的样品组为2.9％,而对苯并［a］芘的解吸结果与菲相反,未接种的对照组为4％,接种的样品组为13％.微生物在土壤与沉积物吸附PAHs的过程中起主导作用.     

北京餐饮源排放细粒子理化特征及其对有机颗粒物的贡献

调研了北京餐饮业发展现状,通过在线监测、采样分析等手段研究北京4家不同烹调方式的餐馆所排放颗粒物的质量浓度、粒径分布、形貌特征、化学组分,并初步估算餐饮源排放细粒子对北京细粒子中颗粒有机物的贡献.结果表明,餐馆的原料、烹饪过程、油烟去除装置以及客流量都会影响餐馆所排放颗粒物的物理、化学性质.样本餐馆营业期间排放颗粒物PM_{2 .5}质量浓度是当日环境大气PM_{2 .5}质量浓度的8～35倍,PM_{1 .0}在PM_{2 .5}的质量浓度中约占50%～85%.餐饮源排放颗粒物多以固态和液态颗粒物形貌存在,化学组分质量百分数由多到少依次是有机物、无机离子和元素碳,分别占到PM_{2 .5}质量浓度的70%左右、5%～11%和小于2%.初步估计结果表明,北京餐饮源排放细粒子对有机颗粒物的贡献和交通源的排放相当,成为北京细粒子有机颗粒物的主要来源之一.认识餐饮源排放颗粒物的理化性质,可以为改善北京空气质量和保证居民身体健康提供数据支持.     

沸石强化生化装置脱氮功能的效果及机理初探

针对石化工业废水开展沸石强化脱氮处理试验研究,通过比较沸石浓度25mg/L与空白,以及沸石浓度25 mg/L与50mg/L两阶段脱氮效果,探讨沸石促进脱氮功能的机理,结果表明,曝气池中投加沸石可明显提高氨氮和总氮的去除率,硝化细菌总数和硝化功能也得到增强。与空白对照组相比, 沸石浓度25mg/L的试验组运行稳定后,氨氮去除率提高约10%~13%,总氮去除率约提高13%,出水中NO3--N含量约提高100%,氨氮与总氮之比下降6%,内源硝化耗氧呼吸速率可提高138%,硝化细菌总数是空白对照组2.2folds。沸石浓度提高到50mg/L后,试验组的脱氮效果略有增加,但效果不明显。通过对试验结果的关联分析,认为沸石提高系统脱氮能力的原因一方面是因为沸石对NH4+及硝态氮的交换吸附,另一方面NH4+离子富集于沸石表面及内部、沸石颗粒独特的好氧-缺氧微环境,以及沸石离解出CO32- 或HCO3-增加碱度等条件,促进了硝化细菌和反硝化细菌的生长,从而提高了系统脱氮能力。     

Alga-lysing bioreactor and dominant bacteria strain

Alga-lysing bacteria have been paid much attention to in recent years. In this study, the alga-lysing strain P05 which was isolated from an immobilizing biosystem was immobilized by coke and elastic filler, forming two biological reactors. The removal efficiencies of algae, NH4^＋-N and organic matter using the two reactors were studied. The results showed that strain P05 was an ideal algal-lysing bacteria strain because it was easy to be immobilized by coke and elastic filler which are of cheap, low biodegradability and the simple immobilization procedure. After 7 d filming, the biological film could be formed and the reactors were used to treat the eutrophic water. These two reactors were of stability and high effect with low cost and easy operation. The optimal hydraulic retention time （HRT） of each reactor was 4 h. The algae removal rates were 80.38% and 82.1% （in term of Chl-α） of coke reactor and filler reactor, respectively. And that of NH4^＋-N were 52.3% and 52.7%. The removal rates of CODMn were 39.03% and 39.64%. The strain P05 was identified as Bacillus sp. by PCR amplification of the 16S rRNA gene, BLAST analysis, and comparison with sequences in the GenBank nucleotide database.     

Assessing field vulnerability to phosphorus loss in Beijing agricultural area using Revised Field Phosphorus Ranking Scheme

Guanting Reservoir,one of the drinking water supply sources of Beijing,suffers from water eutrophication.It is mainly supplied by Guishui River.Thus,to investigate the reasons of phosphorus(P)loss and improve the P management strategies in Guishui River watershed are important for the safety of drinking water in this region.In this study,a Revised Field P Ranking Scheme(PRS)was developed to reflect the field vulnerability of P loss at the field scale based on the Field PRS.In this new scheme,six factors are included, and each one was assigned a relative weight and a determination method.The affecting factors were classified into transport factors and source factors,and,the standards of environmental quality on surface water and soil erosion classification and degradation of the China were used in this scheme.By the new scheme,thirty-four fields in the Guishui River were categorized as"low","medium"or"high"potential for P loss into the runoff.The results showed that the P loss risks of orchard and vegetable fields were higher than that of corn and soybean fields.The source factors were the main factors to affect P loss from the study area.In the study area,controlling P input and improving P usage efficiency are critical to decrease P loss.Based on the results,it was suggested that more attention should be paid on the fields of vegetable and orchard since they have extremely high usage rate of P and high soil test of E Compared with P surplus by field measurements,the Revised Field PRS was more suitable for reflecting the characteristics of fields,and had higher potential capacity to identify critical source areas of P loss than PRS.     

氯碱企业生产过程中的重大危害分析及对策

分析了氯碱企业生产过程中的重大危害为中毒和火灾爆炸,提出了相应的对策.     

巢湖周围池塘氮、磷和有机质研究

巢湖周围池塘众多,根据池塘位置和地表径流补给差异,池塘可以分为村庄内池塘、毗邻村庄池塘和农田区域池塘(远离村庄的池塘).本研究采集了巢湖周围136口池塘上覆水和沉积物样品,调查巢湖周围池塘中氮、磷以及有机质污染现状.结果表明,池塘上覆水中总氮、氨氮、硝态氮、亚硝态氮、总磷、溶解态磷和COD平均含量分别为2.53、0.65、0.18、0.02、0.97、0.38和51.58mg·L-1;池塘沉积物中总氮、氨氮、硝态氮、亚硝态氮、总磷、无机磷、有机磷和烧失量平均含量分别为1575.36、35.73、13.30、2.88、933.19、490.14、414.75mg·kg-1和5.44%;90%以上的池塘总氮、总磷含量达到或超过富营养化水平.位于村庄内的池塘上覆水和沉积物中总氮和氨氮的含量显著高于位于农田区域的池塘.上覆水和沉积物中无机氮表现为:氨氮硝态氮亚硝态氮.池塘上覆水和沉积物中有机质与总氮、总磷之间存在显著的正相关性.池塘中氮、磷和有机物质主要为陆源性输入,池塘位置和径流补给方式明显影响其中的氮、磷和有机质含量.通过截留径流中的氮、磷和有机质,池塘能够有效减少进入巢湖的营养盐含量.