分散液液微萃取-气相色谱/质谱法测定水中阿特拉津

建立了简便、快速、有效的分散液液微萃取(DLLME)-气相色谱/质谱技术萃取水样中痕量阿特拉津的新方法。通过试验确定最佳萃取条件。     

SPME-GC/MS测定扎龙底泥中邻苯二甲酸酯

本文采用固相微萃取前处理方法与气相色谱—质谱联用技术相结合对扎龙底泥中邻苯二甲酸二丁酯(DBP)和邻苯二甲酸(2-乙基己基)酯(DEHP)进行测定。     

固相萃取-原子荧光光谱法测定土壤中的砷

采用硝酸-氢氟酸-盐酸体系微波消解土壤并结合On-Guard ⅡH柱去除消解液中重金属,原子荧光光谱法测定土壤中的砷。本方法前处理操作过程简单、省时、省力、酸用量少,砷的加标回收率为94.4％～105.6％,能够满足环境监测分析的要求。     

1株耐冷兼性嗜碱好氧反硝化菌的分离鉴定及反硝化特性

以传统微生物富集分离方法,从垃圾渗滤液活性污泥中筛选到1株高效好氧反硝化菌,通过形态观察、生理生化特征及16S rDNA序列分析,对菌株进行了鉴定,同时对其好氧反硝化特性和异养硝化功能进行了研究.结果表明,筛选到的好氧反硝化菌株为假单胞菌属(Pseudomonas sp.),命名为GL19,GenBank登录号为(KC710974).碳源、C/N、pH及温度对菌株反硝化活性影响较大.在柠檬酸钠为碳源、C/N不低于15、pH 6~10、溶解氧(DO)4.8~7.7 mg·L-1及温度为15~34℃,硝酸盐氮负荷为140 mg·L-1的条件下,硝酸盐去除率均达100%,总氮(TN)平均去除率为96.5%,最终无亚硝酸盐积累;菌株能以亚硝酸盐氮、氨氮为底物进行高效脱氮,20 h内可将140 mg·L-1的亚硝酸盐氮完全去除,28 h内可将280 mg·L-1的氨氮降至3.11 mg·L-1,氨氮去除率达98.9%.显示该菌具有耐冷、高效脱氮特性,可实现同步硝化反硝化,这对南方地区冬季废水处理具有潜在应用价值.     

厌氧氨氧化菌与其他细菌之间的协同竞争关系

随着污水脱氮行业的蓬勃发展,各种新工艺、新理论层出不穷.厌氧氨氧化(Anammox)工艺以其独特的优点脱颖而出,成为最具应用前景的新工艺.厌氧氨氧化菌作为该过程的执行者目前已发现5属17种,本文主要对5属17种的厌氧氨氧化菌进行总结,并对厌氧氨氧化菌种内关系中的群体感应系统进行详细介绍,此外还介绍了厌氧氨氧化菌与硝化菌、反硝化菌以及厌氧甲烷氧化菌之间的协同与竞争关系.最后给出常见竞争因素对厌氧氨氧化种群结构的影响,通过控制竞争因素来实现对厌氧氨氧化种群结构的调节.本文将厌氧氨氧化菌微生物生态学与厌氧氨氧化污水处理工艺相结合,为厌氧氨氧化工艺在污水生物处理中的应用提供理论依据.     

聚乳酸/淀粉固体缓释碳源生物反硝化研究

以被硝酸盐氮污染的地下水为研究对象,利用共混/熔融聚合技术将聚乳酸和淀粉混合,制备成兼具碳源和生物载体的缓释碳.并考察不同质量比(聚乳酸∶淀粉为8∶2、7∶3、6∶4、5∶5)的缓释碳在反硝化间歇试验中硝氮、亚硝氮和COD的去除效果,结果表明,当聚乳酸/淀粉质量比为5∶5的缓释碳,其反硝化效果最佳,硝氮去除率达99%;以该比例的缓释碳进行反硝化填充柱连续动态试验时,反应器中反硝化效果显著,出水硝氮浓度在2 mg·L-1以下,为开发环境友好的可控性缓释碳源提供了科学依据.     

Sources of nitrous and nitric oxides in paddy soils：Nitrification and denitrification

Rice-paddies are regarded as one of the main agricultural sources of N 2O and NO emissions. To date, however, specific N2O and NO production pathways are poorly understood in paddy soils. ^15N-tracing experiments were carded out to investigate the processes responsible for N2O and NO production in two paddy soils with substantially different soil properties. Laboratory incubation experiments were carried out under aerobic conditions at moisture contents corresponding to 60% of water holding capacity. The relative importance of nitrification and denitrification to the flux of NaO was quantified by periodically measuring and comparing the enrichments of the N2O, NH~-N and NO3-N pools. The results showed that both N2O and NO emission rates in an alkaline paddy soil with clayey texture were substantially higher than those in a neutral paddy soil with silty loamy texture. In accordance with most published results, the ammonium N pool was the main source of N2O emission across the soil profiles of the two paddy soils, being responsible for 59.7% to 97.7% of total N2O emissions. The NO3-N pool of N2O emission was relatively less important under the given aerobic conditions. The rates of N2O emission from nitrification （N2On） among different soil layers were significantly different, which could be attributed to both the differences in gross N nitrification rates and to the ratios of nitrified N emitted as NzO among soil layers. Furthermore, NO fluxes were positively correlated with the changes in gross nitrification rates and the ratios of NO/N2O in the two paddy soils were always greater than one （from 1.26 to 6.47）. We therefore deduce that, similar to N2O, nitrification was also the dominant source of NO in the tested paddy soils at water contents below 60% water holding capacity.     

高铁动车段集便器污水处理调研及优化脱氮分析

基于对高铁动车段污水的调研,针对集便污水具有高氨氮、低碳氮比特征,传统处理工艺难以充分满足《污水排入城镇下水道水质标准》(GB/T 31962-2015)氮排放限值要求,对比分析高效生物脱氮工艺与传统生物脱氮工艺.结果 表明,短程硝化反硝化和厌氧氨氧化工艺具有明显的脱氮效能和经济效益,可有效降低运行成本.     

人工湿地氮转化与氧关系研究

应用N转化迁移模型分析廊道式人工湿地氮转化与氧供应的关系,验证目前湿地全程硝化反硝化脱氮机制的有效性.对各个廊道进出水NH₄⁺-N、NO₃^--N、TN、B₅、DO进行了测定和分析.在水力负荷5cm/d条件下,各廊道湿地有机氮矿化率为0.01～0.28g·(m²·d)^-1、氨氮硝化率0.50～1.54 g·(m²·d)^-1,反硝化率0.41～1.13 g·(m²·d)^-1(占总氮损失的3.4%～35.4%)、植物净吸收氮0.07～0.26 g·(m²·d)^-1(占总氮损失的7%～33%).硝化反硝化与有机质降解同时进行,在进水端最明显,这与传统认识相悖.按照全程硝化化学计量学得到的硝化需氧量(NOD)高于实际的表面复氧和植物根系放氧.最后对在高浓度有机质存在条件下,能减少对氧需求的2种新型脱氮机制进行了讨论.     

北京官厅水库中农药类内分泌干扰物分布和来源

研究了北京官厅水库中农药类内分泌干扰物污染水平、分布特点和来源.结果表明,官厅水库及其支流水体受到农药类内分泌干扰物轻度污染.从农药在官厅水库中的分布推断,官厅水库以及各支流周边地区及农田排水渠是水库中农药的重要来源.底泥中农药通过底泥孔隙向表面水扩散,是表面水农药的1个污染源.由于水库周边较多的农业活动,可能导致水中农药浓度提高.为了减少污染和水生生物对内分泌干扰物的暴露,需要进行定期监测,减少农药的使用和农事操作.