1990—2018年于桥水库流域氮磷浓度变化趋势及影响因素

基于1990—2018年于桥水库流域入库河流与水库的逐月总氮(TN)和总磷(TP)监测数据,整理并分析了1990-2002、2003—2014和2015—2018年3个时段TN、TP浓度和氮磷比(TN/TP)的时空变化特征,探究流域内点面源污染削减、调水、氮磷滞留等对营养盐浓度变化的影响。结果表明,1990—2018年于桥水库TN浓度年均值在1.14～3.74 mg/L之间,水库TP浓度年均值在0.025～0.131 mg/L之间,多年TN/TP平均值为45,远高于淡水磷限氮磷比,是磷限水库。于桥水库流域5个测点中,沙河TN浓度最高,黎河TP浓度最高,入库TN、TP浓度大于库区,水库TP滞留率略大于TN。水库TN、TP浓度在2000s中后期下降,之后出现反弹。原因是2003年水源保护工程实施后,入库营养物浓度降低;2014年底南水北调中线一期工程通水后,于桥水库的引滦水量减少,TN的稀释效应弱化,上游来水TP浓度上升与水库内夏秋两季浮游植物的增殖,导致第三时段水库内TP浓度上升。基于月尺度水质分析,夏季水库TN浓度最低,TP浓度达到峰值,主成分分析表明,历年6—10月的水库Chl.a浓...     

输水对于桥水库水质时空变化的影响

研究输水对水库水质时空变化的影响有助于科学预测水体富营养化及防控水华暴发.本文以于桥水库为例,基于2011-2015年实测资料分析入库水质——水温、总氮（TN）、总磷（TP）与流量的相关关系;并以2012年为典型年,运用平面二维"水动力-水质"数学模型模拟库区水质变化随入库流量的响应关系.研究表明：（1）11月-次年4月水库水温受气温控制,入库与库区水温差异不明显;5-10月,非输水期库区上游水温最高,输水期入库温差随流量增大呈线性升高趋势,库区上游水温明显降低且出现谷值;（2）营养物（TN、TP）浓度变化规律全年基本一致,非输水期入库TN浓度高、TP浓度低,营养物在果河段汇集,库区营养物衰减浓度降低且浓度梯度平缓;输水期入库TN浓度随流量增大呈幂函数降低趋势、TP浓度呈线性升高趋势,营养物被输移至库区上游导致库区TN、TP浓度升高且浓度梯度增大;（3）库区水温谷值及TN、TP浓度峰值均滞后于果河流量变化,且库区南岸比北岸更易受果河来流影响污染更严重.     

引水等综合整治后杭州西湖氮、磷营养盐时空变化(1985—2013年)

经引水等综合整治后,西湖外湖、西里湖总磷(TP)浓度累计下降58%和78%,总氮(TN)浓度累计下降16.7%和7.7%,透明度提高100%~200%,富营养状态得到极大缓解.比较1986年治理前,西湖各湖区因来水、引水和排水格局差异较大,TP浓度的年内变化特点及驱动因素也存在较大差异:杨公堤以西的上游湖区因优质水源补充TP浓度总体较低,同时受流域降雨径流面源输入影响,呈现时段性升高;杨公堤和苏堤之间的中游湖区优质水源补充量最大,湖区水体更新最快,TP浓度最低且变化相对最为稳定;苏堤以东的外湖区水体更新相对最慢,在夏、秋高温季节因底泥污染释放,TP浓度出现峰值.因外来引水量大且未经脱氮处理,西湖各湖区TN年内变化基本与钱塘江取水口TN浓度变化一致,同时因流域降雨径流面源输入而出现时段性波动.基于TP质量平衡模型分析,各湖区水质空间差异主要受水体年交换次数影响,其次受单位水体的年污染负荷影响.     

亚热带地区典型水库流域氮、磷湿沉降及入湖贡献率估算

为了探究汤浦水库流域氮、磷湿沉降对水库水体营养的贡献率,本研究对2014 2015年的汤浦水库流域4个采样点的雨水及3条溪流进行样品收集,测定其中磷和不同形态氮的质量浓度,分析汤浦水库流域大气湿沉降中氮、磷营养盐的分布特征,并估算氮、磷营养盐湿沉降对汤浦水库入库负荷的贡献率.结果表明:湿沉降中总氮(TN)平均浓度为1.02±0.58 mg/L,氨氮、硝态氮和有机氮浓度占TN浓度的比例分别为60.65%、34.07%和5.28%;总磷(TP)平均浓度为0.033±0.028 mg/L.4个采样点湿沉降中氮、磷浓度均表现为冬春季(少雨季)高、夏秋季(多雨季)低.空间上,王化点位的各形态氮和总磷浓度显著高于其他3个采样点.TN和TP年均湿沉降通量约为18.15和0.62 kg/(hm~2·a),年均沉降总量为834.94和28.39 t;库区TN和TP水面湿沉降量为24.14和0.82 t,直接贡献率占河流输入的1.77%和3.07%.湿沉降来源的氮、磷营养盐随河流输入的间接贡献率为8.3%和4.6%.综上所述,氮、磷湿沉降是水库外源营养的重要输入部分,深入掌握其时空分布特征及入库贡献率是进一步加强流域管理和减轻水库外源营养输入的重要前提.     

京蒙沙源区水库大气磷干、湿沉降污染特征

为阐明典型沙源区水库大气磷干、湿沉降的污染特征及其对水域磷素污染的贡献,为水库富营养化治理提供科学依据,以京蒙沙源区大河口水库库区为研究区,于2014年沿水库岸边布设12个大气沉降监测站点,采集干、湿沉降样品,测定干、湿沉降中总磷(TP)浓度,计算全年各月大气TP干、湿沉降通量和年入库TP污染负荷量.结果表明:研究区大气干、湿沉降季节差异显著,全年各月TP干沉降通量变化范围为4.89~35.76 kg/(km~2·月),主要集中在春季4月和秋季10月.最大TP干沉降通量出现在春季风沙最为严重的4月;湿沉降主要集中在夏季(6—8月),最大TP湿沉降通量出现在降雨量最大的8月,为28.88 kg/(km~2·月),且TP湿沉降通量与降雨量呈显著正相关.2014年大气TP沉降入库污染负荷量为0.719 t,占同期滦河和吐力根河两条河流入库TP污染负荷比率为51.17%,成为影响和限制大河口水库磷营养盐水平的重要源项之一.     

基于EFDC模型的深圳水库富营养化模拟

基于EFDC模型构建了深圳水库三维水动力和富营养化定量模拟模型.分别用2009年和2010 2011年流量、水位和水质等观测数据对模型进行了校正和验证,准确地反映了深圳水库的水动力和水质变化过程.在此基础上,假定支流污染截排、水库调度和降低东江引水污染负荷3种情景进行深圳水库富营养化数值模拟,3种情景下库中Chl.a峰值浓度分别降低1.0%、16.4%和46.3%,平均浓度分别降低1.3%、29.8%和29.9%.深圳水库具有良好的交换能力,尚未出现水华暴发,但入库营养盐负荷高,存在较大的富营养化风险;在目前沙湾河污水已经截排的基础上再实施支流污染控制,对水质改善和藻类控制作用已不明显;水库调度和削减东江引水污染负荷对深圳水库水质和富营养化改善明显,能够有效降低水华发生的风险.     

南亚热带典型调水型水库—广东大镜山水库的富营养化特征分析

调水型水库是一种以抽水入库为主要来水水源的水体,是沿海地区重要的供水水源地.为了解这类水库的富营养化特点,于2005年全年每月2次对地处我国南亚热带地区(广东珠海市)的大镜山水库进行采样和监测.监测和测定指标主要包括氮、磷营养盐浓度、水温、透明度及叶绿素a浓度等,结合水库水文数据对水库富营养化特征和主要的影响因素进行分析.结果表明,2005年,大镜山水库的富营养化状态TSI_M指数在45-53之间,水库处于中富营养状态,多数时间处于富营养状态.水体富营养化主要参数表现出明显的季节变化,即叶绿素a浓度和富营养化状态指数在早春和晚秋出现两个峰值,明显地与温带富营养化水体在夏季出现单个峰值的特征不同.调水入库增加了水库营养盐负荷的同时,也在很大程度上影响了水库水动力学过程,与夏季的集中强降雨一起成为影响该水库富营养化的关键因素,这些因素改变了浮游植物群落对营养盐的直接响应,导致叶绿素a浓度与总磷、总氮浓度之间呈弱相关关系,降水和调水量在时间上相对配置重要性决定了叶绿素a浓度与营养盐浓度的关系.     

江西省万安水库对氮、磷营养盐的滞留效应

以江西省万安水库为研究对象,于2007-2009年丰、枯水期对水库进行了人库、出库水样采集,研究了万安水库对氮、磷营养盐的滞留效应.结果表明,万安水库对氮、磷营养盐存在显著滞留作用.DIN浓度和输送通量整体均表现为入库>出库,受径流量季节变化的影响.不同时期DIN的滞留情况整体表现为枯水期<丰水期;TP浓度和输送通量整...     

滇池水体不同形态磷负荷时空分布特征

利用Arc GIS空间插值的方法,通过2013年逐月监测(12个月)36个站点水量及不同形态磷浓度,揭示滇池水体磷浓度和磷负荷的时空变化,并探讨不同形态磷负荷的组成贡献,旨在为进一步实施滇池水污染治理及污染负荷控制提供依据.结果表明:滇池水体总磷(TP)浓度在0.13~0.46 mg/L之间,其中颗粒态磷(PP)浓度占TP浓度的72.6%,溶解性活性磷(SRP)浓度占TP浓度的12.8%,溶解性有机磷(DOP)浓度占TP浓度的14%;2013年水体TP负荷为251 t/a,其中PP负荷为190 t/a,SRP负荷为26 t/a,DOP负荷为34 t/a;滇池水体PP负荷对TP负荷的贡献最大,为76%,其次为DOP和SRP,贡献分别为13%和10%;TP及不同形态磷浓度与其负荷在季节分布上差异显著,负荷随季节变化呈现秋、冬季较高,春、夏季较低,而浓度呈现夏、秋季较高,冬、春季相对较低的趋势.定量评估滇池水体不同形态磷负荷及其组成贡献,对进一步揭示滇池藻源和泥源内负荷对水污染的贡献具有重要意义.     

南北同枯场景下南水北调中线丹江口水库供水调度方式

南北同枯场景下南水北调中线丹江口水库供水调度是保障水源工程有效供给、优化配置供水水源的重要课题,如何科学制定不同供水对象的供水水量、兼顾水源区及受水区用水需求、充分发挥丹江口水利枢纽的调蓄作用,是南水北调中线工程功能效益发挥的关键.以南水北调中线水源工程丹江口水库为研究对象,深入分析了中线工程通水后丹江口水库供水现状及面临的技术难题,从而提出南北同枯场景的判别标准及相应水库供水调度的方法,揭示了汉江中下游、清泉沟和南水北调中线供水对水库起始供水水位的响应机理,提出"蓄丰补枯、均衡减少"的方法是南北同枯场景下丹江口水库的供水调度方式,不同供水起始水位及供水方式情况下供水调度仿真结果表明,本文所得结论可为丹江口水库在实际运行中制定调度方案提供参考.     

Modelling sediment deposition and phosphorus retention in a river floodplain

Phosphorus (P) is one of the major limiting nutrient in many freshwater ecosystems. During the last decade, attention has been focused on the fluxes of suspended sediment and particulate P through freshwater drainage systems because of severe eutrophication effects in aquatic ecosystems. Hence, the analysis and prediction of phosphorus and sediment dynamics constitute an important element for ecological conservation and restoration of freshwater ecosystems. In that sense, the development of a suitable prediction model is justified, and the present work is devoted to the validation and application of a predictive soluble reactive phosphorus (SRP) uptake and sedimentation models, to a real riparian system of the middle Ebro river floodplain. Both models are coupled to a fully distributed two‐dimensional shallow‐water flow numerical model. The SRP uptake model is validated using data from three field experiments. The model predictions show a good accuracy for SRP concentration, where the linear regressions between measured and calculated values of the three experiments were significant (r² ≥ 0.62; p ≤ 0.05), and a Nash–Sutcliffe coefficient (E) that ranged from 0.54 to 0.62. The sedimentation model is validated using field data collected during two real flooding events within the same river reach. The comparison between calculated and measured sediment depositions showed a significant linear regression (p ≤ 0.05; r² = 0.97) and an E that ranged from 0.63 to 0.78. Subsequently, the complete model that includes flow dynamics, solute transport, SRP uptake and sedimentation is used to simulate and analyse floodplain sediment deposition, river nutrient contribution and SRP uptake. According to this analysis, the main SRP uptake process appears to be the sediment sorption. The analysis also reveals the presence of a lateral gradient of hydrological connectivity that decreases with distance from the river and controls the river matter contribution to the floodplain. Copyright © 2014 John Wiley & Sons, Ltd.     

Quantifying seasonal export and retention of nutrients in West European lowland rivers at catchment scale

To set accurate critical values for the protection of lakes and coastal areas, it is crucial to know the seasonal variation of nutrient exports from rivers. This article presents an improved method for estimating export and in‐stream nutrient retention and its seasonal variation. For 13 lowland river catchments in Western Europe, inputs to surface water and exports were calculated on a monthly basis. The catchments varied in size (21 to 486 km²), while annual in‐stream retention ranged from 23 to 84% for N and 39 to 72% for P. A novel calculation method is presented that quantifies monthly exports from lowland rivers based on an annual load to the river system. Inputs in the calculation are annual emission to the surface waters, average monthly river discharge, average monthly water temperature and fraction of surface water area in the catchment. The method accounts for both seasonal variation of emission to the surface water and seasonal in‐stream retention. The agreement between calculated values and calibration data was high (N: r² = 0·93; p < 0·001 and P: r² = 0·81; p < 0·001). Validation of the model also showed good results with model efficiencies for the separate catchments ranging from 31 to 95% (average 76%). This indicates that exports of nitrogen and phosphorus on a monthly basis can be calculated with few input data for a range of West European lowland rivers. Further analysis showed that retention in summer is higher than that in winter, resulting in lower summer nutrient concentrations than that calculated with an average annual input. This implies that accurate evaluation of critical thresholds for eutrophication effects must account for seasonal variation in hydrology and nutrient loading. Our quantification method thus may improve the modelling of eutrophication effects in standing waters. Copyright © 2011 John Wiley & Sons, Ltd.     

金沙江下游梯级水库对氮、磷营养盐的滞留效应

氮、磷是水域重要的营养或污染物质,大型水库修建将对江河氮、磷物质的输运产生重要影响.以金沙江华弹、向家坝水文站2006-2016年实测水质资料为依据,通过建立污染物浓度与流量比值（TN/Q、TP/Q）与含沙量（S）的关系式,对金沙江下游溪洛渡、向家坝梯级水库蓄水前后进出库总氮（TN）、总磷（TP）浓度及通量的变化特征进行研究.结果表明：（1）华弹站不受蓄水影响,TN和TP浓度在0.38~1.41和0.01~0.73 mg/L之间变化,向家坝站蓄水前TN和TP浓度在0.32~1.33和0.03~0.42 mg/L之间变化,蓄水后在0.35~1.29和0.01~0.05 mg/L之间变化,蓄水后TN浓度较蓄水前略有升高,但TP浓度较蓄水前约降低75%;（2）蓄水前华弹站TN浓度与向家坝站基本接近,TP浓度总体低于向家坝站,蓄水后华弹站TN浓度低于向家坝站,TP浓度明显高于向家坝站;（3）金沙江TN以硝态氮（NO₃^--N）为主,占TN浓度的67.3%~91.8%;（4）两站的TN浓度随流量和含沙量变化较小,TP浓度与流量和含沙量均呈正相关关系;（5）华弹站TN、TP年通量在48357~135827和4720~14163 t之间变化,年均值分别为90337和8932 t,向家坝站蓄水前后TN年通量在64232~130966和71675~149647 t之间变化,蓄水后通量总体高于蓄水前,TP年通量在8851~18624和3131~7300 t之间变化,蓄水后通量远低于蓄水前;（6）水库蓄水对出库TN浓度与通量无明显影响,但TP浓度与通量较蓄水前明显降低,其中通量年均滞留率约为67.0%.     

Dynamics of phosphorus compounds in a lowland river system: Importance of retention and non-point sources

Intensive measurements of the fluxes of phosphorus (P) and of P retention were carried out in a Danish lowland watershed (Gjern Å) during two hydrological years (June 1987 to May 1989). Seasonal and short-term variations of P concentrations were measured by intensive automatic sampling covering P fluxes from the entire Gjern Å watershed and two subcatchments: the Gelbæk and Lake Søbygård. Moreover, infrequent sampling was performed in all major tributaries of the river system. Transport of P compounds (dissolved and particulate P) exposed a seasonal pattern which was highly affected by flow conditions, instream processes, as well as point and non-point sources. Stormflow P transport during the two study years (1987-8 and 1988-9) constituted 56 and 61% in the Gelbæk, respectively, compared with 25 and 23% in the Gjern Å, respectively. Particulate P transport in the Gelbæk constituted 56 and 75% of annual total P transport during the two years compared with 77 and 75% in the Gjern Å. The magnitude of monthly baseflow and stormflow total P loads was significantly correlated with the mean monthly discharge during baseflow and stormflow in the Gelbæk, whereas only stormflow loads were correlated to discharge in the Gjern Å. In situ measurements of retention showed that the maximum amount of P stored in the Gelbæk during summer (June to August) was 22gPm^?2 (1988) compared with 27gPm^?2 (1987) in the Gjern Å. Lake Søbygård was a P source during summer but a P sink during winter and on an annual basis the net P released was 810 and 1420 kg, which corresponded to 7 and 20% of the annual P export from the watershed, respectively. Retention constituted about 30% of gross P transport in the Gelbæk during summer compared with 20% in the Gjern Å. Resuspension of retained P during stormflows in September 1987 constituted 94% of the stormflow P transport and 54% of the total P transport. Monthly total P and dissolved reactive P (DRP) mass balances for the main channel of the Gjern Å revealed a significant DRP retention over 17 months (p < 0.05) caused by P adsorption on sediments and biological uptake. On an annual basis the main channel was a sink of DRP (1220 and 1660 kg P) but a source of total P (3440 and 1000 kg P). implying that the channel is an important source of particulate P. Bank erosion proved to be a significant P source in the main channel of Gjern Å, whereas P delivery from soil erosion was possibly of minor importance. The annual non-point P export from two intensively sampled catchments was significantly higher (0.89 and 0.45 kg Pha^?1 yr^?1) than from the five extensively sampled subbasins (0.43 and 0.17 kg Pha^?1 yr^?1). No significant relationship could be established between non-point P export and the proportion of arable land and soil type. Only for the wet year of 1987-8 was a significant relationship established between non-point P export and the P load from scattered dwellings outside sewage areas in five subbasins.     

RETENTION OF WATER AND SEDIMENT BY GRASS STRIPS

This paper discusses aspects of grass vegetation in relation to soil erosion control. By means of a literature research, four options for using grass vegetation were recognized, each having its own requirements concerning maintenance, vegetation characteristics and field layout. The main filter mechanisms, application in the field and effects on runoff and soil loss are discussed. Field experiments on filter strips were carried out to determine whether literature data for water and sediment retention by vegetation can be applied to sloping loess soils in South Limburg (The Netherlands). The field experiments simulated a situation in which surface runoff carrying loess sediment from an upslope field enters a grass strip. The retention of water and sediment by grass strips was determined by measuring runoff discharge and the sediment concentration at the inflow and outflow points from bordered plots. Two locations with different grass age and agricultural management were studied. Results show that grass strips are effective in filtering sediment from surface runoff as long as concentrated flow is absent. Outflow sediment concentrations could be described as a function of inflow concentrations and strip width. Reductions of sediment discharge varied between 50–60, 60–90 and 90–99% for strips of 1, 4–5 and 10 m width, respectively. Old grass, extensively used as pasture, is more effective in reducing erosion than the younger grass which was often accessed by tractors for mowing. Differences in water retention between both grass locations appear to be caused mainly by differences in grass density.     

滇池水-沉积物界面磷形态分布及潜在释放特征

通过现场调查和室内模拟实验,对滇池35个上覆水-沉积物磷的分布特征以及沉积物中磷释放动力学特征进行研究,结果表明:滇池表层沉积物中不同形态磷含量表现为:有机磷(OP)(1482.49±1156.82 mg/kg)钙结合态磷(Ca-P)(865.54±558.40 mg/kg)金属氧化物结合态磷(Al-P)(463.77±662.18 mg/kg)残渣态磷(Res-P)(218.52±83.11 mg/kg)可还原态磷(Fe-P)(128.13±101.56 mg/kg)弱吸附态磷(NH4Cl-P)(2.26±3.05 mg/kg);滇池上覆水草海总磷浓度处于劣Ⅳ类水平,外海不同湖区总磷浓度介于Ⅳ~Ⅴ类之间;滇池水体中的磷以颗粒态磷含量最高;滇池表层沉积物中磷的释放是由快反应和慢反应两部分组成.释放过程主要发生在前8 h内;不同区域沉积物磷的最大释放速率、最大释放量、磷的释放潜力平均值均表现为:草海外海北部外海南部湖心区;滇池表层沉积物中磷的释放主要由NH4Cl-P、Fe-P、Al-P和OP进行,其中,NH4Cl-P和Fe-P所占比重较大;磷的释放与上覆水中溶解性总磷、溶解态无机磷和溶解态有机磷呈显著正相关,预示着上覆水中磷的迁移转化更多地受到水-沉积物界面浓度梯度的控制,进一步说明不能以总磷含量来评价湖泊磷素释放的状况,需与磷形态及分布特征相结合进行分析.