香溪河沉积物-水界面的营养盐交换特征

为研究香溪河库湾沉积物-水界面的营养盐交换特征,于2016年6月采集香溪河库湾上覆水和沉积物间隙水样品,分析不同形态氮、磷的空间分布特征并进行相关性分析,计算沉积物-水界面氮、磷的释放通量.结果表明:香溪河库湾上覆水和沉积物间隙水中ρ（TP）的变化范围分别为0.484~0.927和0.511~2.220 mg/L,ρ（TN）的变化范围分别为0.739~4.302和3.571~14.011 mg/L;上覆水和沉积物间隙水中氮、磷质量浓度在沿程和垂向上具有一定的变化规律,上游区域沉积物间隙水中氮、磷质量浓度大于下游区域,沉积物间隙水中氮、磷质量浓度明显大于上覆水;香溪河沉积物总体上表现为PO₄3--P和NH₄+-N的"源",中下游区域沉积物表现为NO₃--N的"源",而中上游区域表现为NO₃--N的"汇";PO₄3--P的释放通量范围为0.129~0.339 mg/（m2·d）,NH₄+-N的释放通量范围为0.213~1.415 mg/（m2·d）,NO₃--N的释放通量范围为-1.109~3.446 mg/（m2·d）.研究显示,上覆水的环境条件对于沉积物-水界面营养盐交换存在一定的影响,但影响程度各有不同.      

高含氮印染废水强化脱氮处理组合工艺

为考察UASB-A/LO/O（缺氧/低氧/好氧）组合工艺的实际应用效果,将该工艺应用到规模为6 000 t/d的实际工程中,考察其对高含氮印染废水处理效果,同时采用微生物高通量测序对A/LO/O工艺中的微生物菌群结构进行解析.结果表明:在前处理废水进水流量为100 m3/h,染色废水进水流量为150 m3/h,同时A/LO/O工艺污泥回流比为50%左右情况下,COD_Cr、NH₃-N和TN的去除率分别达到91.6%、95.5%和73.5%;染色和前处理废水在改良UASB内均实现了高效厌氧氨化,染色废水厌氧出水中ρ（NH₃-N）/ρ（TN）保持在80%以上,前处理废水厌氧出水保持在85%以上;调节UASB运行参数可对VFAs（挥发性脂肪酸）进行有效调控,从而为后段反硝化工艺提供高品质碳源,实现高效脱氮;A/LO/O系统对COD_Cr、NH₃-N、TN有较好的去除效果,其脱氮性能主要靠变性菌门（Proteobateria）发挥作用,该系统中低氧池的微生物种类最为丰富且发生短程硝化反硝化,对污染物去除贡献最大,当低氧池△ρ（COD_Cr）/△ρ（TN）在18.6左右时,TN去除率最高,达到82%.研究显示,该组合工艺对工程中高含氮印染废水的脱氮效果良好.      

同步脱氮除磷系统中两种颜色好氧颗粒污泥的微生物群落特征

为研究同步脱氮除磷系统中出现的WG（白色好氧颗粒污泥）外形特点及微生物群落特征,探究其成因,利用SEM（扫描电子显微镜）表征了系统中的WG与YG（黄色好氧颗粒污泥）的微观形态,并采用Illumina HiSeq 2500高通量测序平台对两种好氧颗粒污泥中细菌与真菌的群落组成进行研究.结果表明:WG结构疏松外形不规则,颗粒表面分布大量杆菌;而YG饱满紧实轮廓清晰,颗粒表面分布大量球菌.WG与YG的细菌群落组成相似,但真菌组成差异较大.与YG相比,WG具有更高的细菌和真菌多样性.变形菌门（Proteobacteria）和拟杆菌门（Bacteroidetes）为WG和YG中的细菌优势门,其在WG中的相对丰度分别为68.85%和26.61%,在YG中的相对丰度分别为82.52%和12.30%.Candidatus competibacter、Candidatus accumulibacter和Chiayiivirga为WG中的优势属,相对丰度分别为22.13%、8.95%和7.37%;Candidatus competibacter、Chiayiivirga和Xanthomonas为YG中的优势属,相对丰度分别为47.94%、6.95%和7.06%.子囊菌门（Ascomycota）和Rozellomycota分别为WG与YG中真菌优势门,其在两个样品中的相对丰度分别为50.10%和81.77%.在属水平,WG中存在大量青霉属（Penicillium）和假丝酵母属（Candida）等丝状真菌,为WG的形成提供了框架.研究显示,当YG破碎成为小菌胶团后,附着在真菌框架上,造成了WG的快速形成,同时WG中Candidatus competibacter的相对丰度较低,使其外形疏松、透光性较好,呈现出白色.      

Control of aliphatic halogenated DBP precursors with multiple drinking water treatment processes: Formation potential and integrated toxicity

The comprehensive control efficiency for the formation potentials(FPs) of a range of regulated and unregulated halogenated disinfection by-products(DBPs)(including carbonaceous DBPs(C-DBPs), nitrogenous DBPs(N-DBPs), and iodinated DBPs(I-DBPs)) with the multiple drinking water treatment processes, including pre-ozonation, conventional treatment(coagulation–sedimentation, pre-sand filtration), ozone-biological activated carbon(O_3-BAC) advanced treatment, and post-sand filtration, was investigated. The potential toxic risks of DBPs by combing their FPs and toxicity values were also evaluated.The results showed that the multiple drinking water treatment processes had superior performance in removing organic/inorganic precursors and reducing the formation of a range of halogenated DBPs. Therein, ozonation significantly removed bromide and iodide,and thus reduced the formation of brominated and iodinated DBPs. The removal of organic carbon and nitrogen precursors by the conventional treatment processes was substantially improved by O_3-BAC advanced treatment, and thus prevented the formation of chlorinated C-DBPs and N-DBPs. However, BAC filtration leads to the increased formation of brominated C-DBPs and N-DBPs due to the increase of bromide/DOC and bromide/DON.After the whole multiple treatment processes, the rank order for integrated toxic risk values caused by these halogenated DBPs was haloacetonitriles(HANs)》haloacetamides(HAMs) haloacetic acids(HAAs) trihalomethanes(THMs) halonitromethanes(HNMs) 》I-DBPs(I-HAMs and I-THMs). I-DBPs failed to cause high integrated toxic risk because of their very low FPs. The significant higher integrated toxic risk value caused by HANs than other halogenated DBPs cannot be ignored.     

Capability of cation exchange technology to remove proven N-nitrosodimethylamine precursors

N-nitrosodimethylamine(NDMA) precursors consist of a positively charged dimethylamine group and a non-polar moiety, which inspired us to develop a targeted cation exchange technology to remove NDMA precursors. In this study, we tested the removal of two representative NDMA precursors, dimethylamine(DMA) and ranitidine(RNTD), by strong acidic cation exchange resin. The results showed that pH greatly affected the exchange efficiency, with high removal(DMA 78% and RNTD 94%) observed at pH pk_a-1 when the molar ratio of exchange capacity to precursor was 4. The exchange order was obtained as follows: Ca~(2+) Mg~(2+) RNTD~+ K~+ DMA~+ NH_4~+ Na~+. The partition coefficient of DMA~+to Na~+was 1.41 ± 0.26, while that of RNTD~+to Na~+was 12.1 ± 1.9. The pseudo second-order equation fitted the cation exchange kinetics well. Bivalent inorganic cations such as Ca~(2+)were found to have a notable effect on NA precursor removal in softening column test. Besides DMA and RNTD, cation exchange process also worked well for removing other 7 model NDMA precursors. Overall, NDMA precursor removal can be an added benefit of making use of cation exchange water softening processes.     

覆盖金属氧化物对湖泊沉积物溶解性有机质特征的影响

为揭示不同金属氧化物对湖泊沉积物DOM（溶解性有机质）影响机制,通过室内模拟试验,在沉积物表层分别覆盖Fe、Al、Mn氧化物及湖沙后培养1 a,并利用三维荧光和紫外光谱方法进行表征.结果表明:① 覆盖Al、Fe、Mn氧化物和湖沙主要降低了0~3 cm沉积物的w（DOC）,降幅分别为8.61%、6.27%、22.38%和0.44%. ② 沉积物中DOM的类络氨酸峰（peak B₁）和类色氨酸峰（peak T₂）均产生较大变化.其中三种氧化物均显著降低了上层沉积物中DOM的peak T₂,使底层DOM的peakT₂显著增加. Mn氧化物使DOM的peak B₁降低,Fe和Al氧化物使DOM的peak B₁增加,湖沙则使两类峰均降低. ③ 覆盖金属氧化物改变了沉积物DOM结构特征,其中覆盖Fe氧化物增强了其芳香性,而覆盖Mn氧化物和Al氧化却降低其芳香性,但三者均使DOM腐质化程度及官能团数量增加,并使FI（Fluorescence Index,荧光指数）增大,表明DOM向生物源转化.研究显示,沉积物表层覆盖金属氧化物影响了沉积物中DOM迁移和转化,并促进了其降解,导致其分子量和腐殖化程度增加.      

紫外消毒对城市污水处理厂耐药菌去除的影响研究

通过选取假单胞杆菌、鲍曼不动杆菌以及芽孢杆菌3种耐药菌作为研究对象,研究紫外光变化对这3种耐药菌的去除效果,得出较好的紫外消毒条件,应用到实际的污水处理厂消毒过程中。结果表明,紫外消毒对3种耐药菌都有很好的灭活效果。     

美国市政污水处理排放标准制定对中国的启示

在概述美国市政污水处理排放标准制度体系的基础上,介绍了其制定基于技术的排放限值和基于水质的排放限值的方法,阐述了其制定的科学性,并指出了中国市政污水处理排放标准中存在的相应问题。最后,根据美国制定排放标准限值的经验,对我国污水处理排放标准进行了思考,并提出了科学制定排放标准的方法和建议。     

大冶湖表层水和沉积物中重金属污染特征与风险评价

于2014年4月采集大冶湖表层水和表层沉积物,用原子吸收分光光度法测定其重金属含量,并基于健康风险评价模型和潜在生态风险指数法开展表层水和沉积物重金属污染的潜在健康风险和生态风险评价.结果表明,表层水和沉积物重金属(Ni、Cd、Cu和Pb)含量平均值分别为49.27、2.19、12.18、12.13μg·L~(-1)和78.46、77.13、650.13、134.22 mg·kg~(-1).富集系数显示,Cd、Cu和Pb均为重度富集,尤其是Cd累积最为明显.与国内典型湖泊重金属污染相比,表层水和沉积物中重金属元素含量均相对较高.表层水和沉积物重金属元素均表现为湖湾处含量较高,中部含量较均匀的分布规律,其来源主要受多种人为活动污染.环境风险评价显示,重金属类化学物质通过饮水途径产生健康风险范围为9.77E-08~1.63E-05 a-1,Ni和Cd是水环境健康风险的优先管理对象.沉积物重金属的潜在生态风险高低为CdCuPbNi,其中Cd是生态风险的贡献元素.     

人为干扰对小兴安岭森林湿地土壤碳组分和酶活性的影响

以小兴安岭落叶林沼泽湿地为研究对象,对比研究皆伐地、火烧地和落叶松湿地土壤碳组分和酶活性.结果表明:(1)3种湿地类型土壤SOC含量表现为对照地显著高于皆伐地和火烧地(p0.05),在0~10 cm土层中皆伐地与对照地相比降低了58.38%,火烧地与对照地相比降低了61.96%.皆伐地与火烧地在不同土层的土壤中SOC含量差异不显著(p0.05);DOC含量对照地显著高于皆伐地和火烧地(p0.05).在0~10cm土层中火烧地DOC含量是皆伐地的1.99倍,两者差异不显著(p0.05);不同干扰方式对土壤MBC含量影响的差异主要表现在0~10 cm的土层土壤,对照地分别比皆伐地和火烧地高23.13%和95.79%(p0.05).在不同的土层中皆伐地MBC含量均大于火烧地,与SOC含量的变化趋势一致.(2)与对照地相比,皆伐地与火烧地0~10 cm土层的土壤蔗糖酶活性分别降低了45.59%和36.76%,脲酶活性显著降低了18.22%和55.69%(p0.05),蛋白酶活性降低了19.65%和17.34%,淀粉酶活性降低了6.29%和10.69%.土壤碳组分和酶活性在垂直方向上均表现为随着土层深度增加而减小.皆伐和火烧造成森林湿地土壤碳组分和酶活性降低.