电极-生物膜法反硝化脱氮研究进展

电极 生物膜法是由电化学和生物膜技术相结合而发展起来的一项新型水处理技术 ,在反硝化脱除水中的硝酸盐氮方面具有良好的效果。综述了国内外有关电极 生物膜法反硝化脱氮研究的概况 ,对其基本原理作出探讨 ,并对该法的继续研究作出展望     

EFFECTS OF CROPPING SYSTEMS ON NO3-N LOSSES TO TILE DRAIN1

Abstract: Diverse cropping systems can have significant impacts on nutrient losses through tile drain systems and to surface water bodies (rivers and streams). Increased transport of nitrogen to water bodies can reduce dissolved oxygen and enrich the supply of nutrients, resulting in hypoxic zones. With the objective of reducing the transport of nutrients from agricultural watersheds, long term studies (1990 to 1998) were conducted in Iowa to investigate the impact of tillage, crop rotation, and N-management practices on NO₃-N leaching losses to tile drain water. Results of these studies indicated that continuous corn production systems required higher input of nitrogen fertilizers and resulted in significantly higher NO₃-N leaching losses compared to rotated corn in plots either fertilized with manure or urea ammonium nitrate. Also, rotated corn gave higher corn yields, 8 megagrams per hectare (Mg/ha) versus 6 Mg/ha, than continuous corn. The higher N application rates resulted in increased NO₃-N concentrations in tile water. A strip cropping system with alfalfa lowered NO₃-N concentrations in tile water to less than 10 mg/l. These studies indicated that better land use practices can reduce NO₃-N leaching losses to surface and ground water systems and will help in mitigating environmental concerns of the production agriculture.     

集约化种植区硝态氮在土壤剖面中的分布与累积特征

采用GPS定位、土钻取样的方法,在北京市大兴区14个乡镇的农田土壤中选取了91个土壤剖面,分别在0～20cm、20～40cm、40～60cm、60～80cm4个不同深度取得土壤样品,并在一次种植期结束后,综合考虑种植类型和土壤质地后选取24个重复取样点.在此基础上,分析了种植类型及土壤质地对硝态氮分布及累积情况的影响.结果表明,研究区土壤中的硝态氮含量有随土壤深度的增加呈降低的趋势.露地菜田和设施菜田最容易出现硝态氮淋洗现象,果园和粮田的总体状况较好,但粮田个别地区有一定的污染风险,细质地土壤具有较强的保水保肥能力.大兴区采育镇及长子营镇地区有较高的硝态氮累积量,为硝态氮淋洗污染危险区,应进行合理施肥,以免在一个种植期结束后造成较深层土壤中硝态氮的累积.研究结果可为大兴区地下水环境保护提供参考.     

ANALYSIS OF NITROGEN MANAGEMENT STRATEGIES USING EPIC1

ABSTRACT: This paper illustrates a method of using a hydrologic/water quality model to analyze alternative management practices and recommend best management practices (BMPs) to reduce nitrate-nitrogen (NO₃^--N) leaching losses. The study area for this research is Tipton, an agriculturally intensive area in southwest Oklahoma. We used Erosion Productivity Impact Calculator (EPIC), a field-scale hydrologic/water quality model, to analyze alternative agricultural management practices. The model was first validated using observed data from a cotton demonstration experiment conducted in the Tipton area. Following that, EPIC was used to simulate fertilizer response curves for cotton and wheat crops under irrigated and dryland conditions. From the fertilizer response functions (N-uptake and N-leaching), we established an optimum fertilizer application rate for each crop. Individual crop performances were then simulated at optimum fertilizer application rates and crop rotations for the Tipton area, which were selected based on three criteria: (a) minimum amount of NO₃^--N leached, (b) minimum concentration of NO₃^--N leached, and (c) maximum utilization of NO₃^--M. Further we illustrate that by considering residual N from alfalfa as a credit to the following crop and crediting NO₃^--N present in the irrigation water, it is possible to reduce further NO₃^--N loss without affecting crop yield.     

微污染水源水生物处理中硝酸盐氮的变化

通过中试系统和大型工程 ,探讨了微污染水源水生物处理工艺中硝酸盐氮的变化规律。研究表明 ,微污染水源水生物处理工艺中硝酸盐氮的增加是氨氮生物硝化的结果 ;处理系统启动中硝酸盐氮变化率的变化反映了两类硝化细菌在生长速率和转化能力上的协调关系以及生物膜的成熟过程 ,启动结束时硝酸盐氮变化率趋于 1.0 0 ;稳定运行阶段各工况下处理系统硝酸盐氮变化率均在 1.0 0附近 ;水源水中少量的有机氮和亚硝酸盐氮对氨氮硝化过程无明显影响。硝酸盐氮变化率是描述微污染水源水生物处理系统氨氮硝化状况的重要参数。     

LAND USE AND STREAMWATER NITRATE-N DYNAMICS IN AN URBAN-RURAL FRINGE WATERSHED1

ABSTRACT: Agricultural and residential activities are key non-point sources of nitrogen pollution in urban-rural fringe areas. A GIS-based watershed approach was used to compare land use indicators (septic system and animal unit densities), to streamwater nitrate-N in the Salmon River near Vancouver, B.C., Canada. The density of septic systems was used as an indicator of residential development while animal unit density was used as an indicator of the intensity of agricultural activity. Nitrate-nitrogen (nitrate-N) concentrations as high as 7.1 mg·L^?1 were found in the mid-portion of the watershed during the summer months, when streamflow is low and groundwater comprises a large proportion of water in the stream. The major aquifer supplying water to the midsection of the watershed is contaminated with nitrate-N. A comparison of the relationships between septic system and animal unit density and nitrate-N in the upstream to downstream direction provided evidence that both residential and agricultural activities contribute to elevated nitrate-N in the Salmon River mainstem. In contrast, only septic system density corresponded to the pattern of streamwater nitrate-N in Coghlan Creek, the main tributary to the Salmon River.     

Effect of dissolved organic matter on nitrate-nitrogen removal by anion exchange resin and kinetics studies

The effects of dissolved organic matter (DOM) on the removal of nitrate-nitrogen from the model contaminated water have been investigated utilizing the strong base anion exchange resins. With the increase of gallic acid concentration from 0 to 400 mg/L, the adsorption amount of nitrate-nitrogen on the commercial resins, including D201, Purolite A 300 (A300) and Purolite A 520E (A520E), would significantly decrease. However, the presence of tannin acid has little impact on nitrate-nitrogen adsorption on them. Compared to D201 and A300 resins, A520E resin exhibited more preferable adsorption ability toward nitrate-nitrogen in the presence of competing organic molecules, such as gallic acid and tannin acid at greater levels in aqueous solution. Attractively, the equilibrium data showed that the adsorption isotherm of nitrate-nitrogen on A520E resin was in good agreement with Langmuir and Freundlich equations. The rate parameters for the intra particle diffusion have been estimated for the different initial concentrations. In batch adsorption processes, nitrate-nitrogen diffuse in porous adsorbent and rate process usually depends on t 1/2 rather than the contact time. The pseudo first- and the second-order kinetic models fit better for nitrate-nitrogen adsorption onto A520E resin. The observations reported herein illustrated that A520E resin will be an excellent adsorbent for enhanced removal of nitrate-nitrogen from contaminated groundwater.     

基于15N 同位素示踪技术的地下河硝态氮来源时空变化特征分析

根据2007年10月至2008年10月每月对青木关地下河水的监测,利用~(15)N 同位素示踪技术并结合水化学指标,分析地下河硝态氮来源的时空变化特征.结果表明,地下河出口S2硝态氮浓度(20.35 mg/L)比入口D1(3.20 mg/L)高6倍多.受农业生产施肥和降雨冲刷稀释效应的影响,地下河水硝态氮浓度2007年10月至2008年3月较低且比较稳定,2008年4月至7月较高但受降雨冲刷稀释影响变化较大,2008年8月至9月随降雨减少,土壤中残留的化肥造成地下河水硝态氮浓度偏高.根据NO_3~--δ~(15)N 值识别出了地下河硝态氮来源变化特征为:D1处2007年10月至2008年3月以及2008年7月至10月NO_3~--δ~(15)N 值为-0.857‰±2.01‰(n=9),其硝态氮来源为稻田中残留的化肥;2008年4月、6月中下旬NO_3~--δ~(15)N 值为2.50‰±0.29‰(n=3),其来源为稻田中施用的化肥与土壤有机氮的混合;2008年5月下旬至6月上旬NO_3~--δ~(15)N 值分别为-3.74‰和0.52‰,其来源为稻田中施用的化肥.S2处硝态氮不仅来自上游的化肥,更主要的是来自中下游的耕地、林地土壤渗透水或侧向裂隙水带来的土壤有机氮与化肥,其中2007年10月至2008年3月以及2008年7月至10月NO_3~--δ~(15)N 值为4.77‰±0.73‰(n=9),其硝态氮主要来自于土壤有机氮;2008年4～6月NO_3~--δ～15N 值为3.16‰±0.39‰(n=5),其硝态氮来自于土壤有机氮与化肥的混合.     

河套灌区地下水氮污染状况

河套灌区浅层地下水氮浓度和地下水埋深的季节变化规律调查结果表明:3月地下水NO3--N和TN浓度显著高于5、7和9月,地下水埋深也比5月和7月深。不同类型的井水N浓度差异较大:农田与庭院的井水NO3--N浓度显著高于村庄附近的井水,而NH4+-N和TN则表现为庭院井水浓度显著高于农田和村庄。地下水氮形态以NO3--N为主,全年17.1%的水井地下水NO3--N浓度高于10 mg.L-1,最高达184.4 mg.L-1。在灌溉量和其他生产条件相同的情况下,沙壕渠试验站农场内施肥区井水NO3--N浓度[(17.55±15.02)mg.L-1]明显高于未施肥区[(7.67±4.48)mg.L-1],且65.5%的水样NO3--N浓度超过WHO规定的生活饮用水NO3--N浓度上限值(10 mg.L-1),而未施肥区仅有27.6%的水样超标。井水NO3--N的来源主要为农田氮肥与动物粪肥,当地地下水NO3--N污染已不容忽视。