南淝河施口断面水污染调查与达标对策研究

南淝河作为目前巢湖流域污染最重、水质最差的入湖河道,是巢湖流域治污的重点,也是治理的难点。为全面掌握南淝河及汇水流域水环境质量,通过对南淝河及其主要支流进行水质监测,采用单因子评价方法对南淝河水质现状进行评价分析,结果表明2016年1月～2019年8月南淝河干流水质为劣V类,未达到水功能区管理目标。结合流域范围内水污染现状调查,从支流污染、城镇生活污染、农村面源污染、河道底泥污染和生态基流匮乏等五个方面分析存在的主要水环境问题,提出了控源减排和环境增容两个方面的达标对策,希望能够对推动南淝河水污染治理提供一些可参考的意见。     

巢湖流域产业结构与水污染程度的关系研究——基于灰色关联分析法

采用灰色关联法研究了巢湖流域产业结构与水污染之间的关系,查找分析对巢湖水质影响较大的行业,以期为巢湖水污染治理提供新思路.通过分析2001-2006年合肥市和巢湖市产业结构,表明合肥市在工业方面的电力、食品、冶金等行业对水污染影响较大;巢湖市对水污染的影响更多体现在牧业、渔业.因此,巢湖流域应加大产业结构调整,优化升级第一、第二产业内部结构,大力发展第三产业,以保护流域内水资源环境,促进流域区域经济社会可持续发展.     

各省动态

安徽:巢湖流域禁上排放氮磷项目安徽省今年将重点推进污染减排和淮河、巢湖等重点流域水质稳定好转。今年起,巢湖流域全面禁止新上向巢湖排放氮、磷污染物的工业建设项目。从2009年起,全面停批向河流排放汞、镉、六价铬重金     

巢湖国考,一条跨界支流的备考样本

在不久前闭幕的安徽省环保工作会议上,安徽省环保厅厅长缪学刚指出,安徽省重点流域水质与规划目标要求有较大差距,巢湖流域12个国家考核断面中,仅有4个达到2012年考核要求,1个断面达标率为0。环巢湖11条主要环湖河流中,南淝河、十五里河、派河、店埠河等长期重度污染,氨氮和总磷超标严重,严重影响巢湖湖区水质。今年上半年,国家将对巢湖流域规划实施情况进行     

巢湖流域农村畜牧业发展与非点源污染研究

目前，巢湖流域非点源污染问题突出。着眼于畜牧业和环境的协调发展，通过对研究区畜牧业生产的实地考查、分析和计算得出结论：畜牧业生产的快速发展、不合理和未加利用的畜牧粪便及畜牧业产品生产加工过程中产生的有机污物是巢湖流域非点源污染的重要原因，来源于畜牧业生产的非点源污染的氮就足以使巢湖水质劣于Ⅲ类标准。最后探讨了解决巢湖富营养化的控制措施。     

辽宁省太子河水质现状及影响因素研究

对2015-2020年辽宁省太子河干流断面水质状况进行了统计分析,以氨氮、COD、总磷3项指标分析了太子河水质的沿程变化情况,结果表明,太子河中下游水质整体较差,且主要污染指标为氨氮.结合太子河流域的自然社会属性,支流河水质较差及农业农村污染较重导致这种水质状况,并在此基础上提出了太子河流域水质改善的措施建议.     

环独墅湖水体污染现状评价

为系统分析环独墅湖水体污染现状,采用营养指数和污染因子指数法对研究区表层水体污染现状进行系统研究.研究结果表明,各水质参数存在明显的空间分布差异.总氮(TN)含量均值为3.26 mg/L,属劣Ⅴ类地表水;总磷(TP)含量均值为0.03 mg/L,为Ⅲ类地表水;总Hg含量均值为0.11μg/L,为Ⅳ类地表水;其他水质参数...     

区划调整后巢湖水污染治理的机遇与挑战——基于排污权交易的巢湖水质管理研究

巢湖是中国典型的富营养化湖泊,为国家"三河三湖"重点水污染防治流域之一。行政区划调整为巢湖治污带来了机遇与挑战。在巢湖流域开展排污权交易将是回应区划调整、优化配置环境资源的积极举措。     

沱江富顺段水质分析及污染状况研究

为了解沱江富顺段水质情况,采用相应的国家标准方法对沱江水体的氮、磷、化学需氧量、生化需氧量等指标进行监测。3个监测断面TN、TP的平均浓度分别为3．31mg／L、0．247mg／L,其中TN含量超标3倍以上,TP含量超过标准的1．2倍,建议相关部门应在河流平水期和枯水期严格控制氮、磷的排放,可通过调高工业废水、污水处理厂氮、磷排放标准,缓解沱江氮、磷污染程度。     

巢湖流域非点源污染来源、影响及控制研究

巢湖是我国五大淡水湖之一,其生态环境安全问题十分突出。随着流域内工业废水和城市污水等点源污染改善的同时,来自农业活动、生活垃圾等的非点源污染成为巢湖水环境污染、湖泊富营养化的重要影响因素。本文分析了,巢湖流域非点源污染的主要来源及其对生态环境所造成的影响,在此基础上进一步概括当前控制巢湖流域非点源污染的主要管理措施。     

LABORATORY EXPERIMENTS AS AN AID TO LAKE RESTORATION DECISIONMAKING1

ABSTRACT: The choice of a lake rehabilitation technique can be assisted by laboratory experiments concerned with the composition and properties of the sediments. This work on Sawgrass Lake, Pinellas County, Florida, provides an example of the type of laboratory information that can be useful towards making decisions regarding the most effective restorative techniques. Experiments include chemical analysis of sediment (water content, organic content, pesticides, nutrients), rate of sediment compaction and rehydration at ambient conditions, and the effect of treatment with alum and other chemicals.     

SIDE EFFECTS OF 58 YEARS OF COPPER SULFATE TREATMENT OF THE FAIRMONT LAKES,MINNESOTA1

The shallow Fairmont Lakes in southern Minnesota have been treated with copper sulfate for 58 years to reduce excessive algal growth. Copper sulfate was applied to five lakes at cumulative rates upo to 1647 kg/ha (1470 1b/acre), totaling 1.5 million kilograms. Data collected since treatment of the Fairmont Lakes began in 1921 provide alarming insights into lake responses to sustained chemical treatment with copper sulfate. Short-term and long-term effects have occurred. Short-term effects include: a) the intended temporary killing of algae, b) dissolved oxygen depletion by decomposition of dead algae, c) accelerated phosphorus recycling from the lake bed and recovery of the algal population within 7 to 21 days, and d) occasional fish kills due to oxygen depletion or copper toxicity or both. Long-term effects are shown to include: a) copper accumulation in the sediments, b) tolerance adjustments of certain species of algae to higher copper sulfate dosages, c) shift of species from green to blue-green algae and from game fish to rough fish, d) disappearance of macrophytes, and e) reductions in benthic macroinvertebrates. The conclusion is that while copper sulfate treatments enjoy great popularity because they kill and remove algae almost instantaneously, other immediate or cumulative side effects can be harmful to many other aquatic organisms.     

THE USE OF A SIMPLE MODEL AND UNCERTAINTY ANALYSIS IN LAKE MANAGEMENT1

ABSTRACT: A simple, black-box lake model was developed for phosphorus, using nonlinear regression analysis on a data base of north temperate lakes. The uncertainty associated with the model was then combined with the parameter uncertainty and the independent variable uncertainty to provide an estimate of the confidence limits associated with a predicted value. The prediction uncertainty is often neglected, yet it is an important measure of the usefulness of a model. Prediction uncertainty reflects the modeler's confidence in the model, and it should be used by a decision maker as a weight indicating the value of the model prediction. A procedure is outlined that combined lake modeling and uncertainty analysis for use in lake quality assessment and lake management. An example is provided illustrating the use of this procedure in nutrient budget sampling design, data analysis, and the evaluation of lake management strategies for a 208 program in New Hampshire.     

LAKE LEVEL DRAWDOWN AS A MACROPHYTE CONTROL TECHNIQUE1

ABSTRACT: Lake drawdown as a management or restoration technique for controlling macrophytes in eutrophic lakes is reviewed for effectiveness, longevity, and positive and negative impacts. Drawdown can be effective but is species specific, and some nuisance plants are resistant or stimulated. The responses of 63 nuisance plants are reviewed. Advantages of the technique include low cost, absence of toxic chemicals, enhancement of fisheries, and the opportunity to carry out other lake improvements. Drawbacks include nutrient release, algal blooms, low dissolved oxygen, lake user dissatisfaction during the process, and failure to refill. The technique is recommended for situations where susceptible species are the major nuisance and where prolonged (1–2 months) dewatering of sediments under rigorous conditions of heat or cold is possible.     

我国湖泊富营养化问题及防治对策

富营养化是我国湖泊的主要问题,它不但制约了湖泊资源的可利用性,而且直接影响到人类的健康生存与社会经济的持续发展.分析了我国湖泊富营养化的现状、危害、产生的原因,提出了防治对策.     

REVIEW OF A SEVENTEEN-YEAR CHLOROPHYLL RECORD AS IT PERTAINS TO THE TROPIIIC STATUS OF LAKE OKEECHOBEE,FLORIDA, USA1

ABSTRACT: A 17-year record of chlorophyll a at eight limnetic sampling stations was used to evaluate putative changes in the trophic status of Lake Okeechobee, a shallow polymictic lake located in the subtropical environment of South Florida. Significant spatial differences were observed in the temporal patterns and variability of chlorophyll a concentrations. The highest chlorophyll a values were found in the northern and northwestern regions of the lake. The center of the lake, subject to high levels of non-algal suspended solids, exhibited relatively low chlorophyll a values and coefficient of variation. The lowest chlorophyll a values were observed at the southernmost sampling station in the lake. This was also the station that showed a significant upward trend in annual mean chlorophyll a values over the 17-year period of record. Examination of the relationship between chlorophyll a and three key environmental variables (i.e., total phosphorus concentration, phosphorus loading, and lake stage) revealed significant correlations at two out of the eight stations. The overall results of this study indicate that spatial and temporal disparities in the distribution and dynamics of chlorophyll a in Lake Okeechobee mandate more temporally and spatially intense approaches to the evaluation of trophic state than used in previous studies.     

IN-LAKE WATER QUALITY MANAGEMENT PLAN FOR A RECREATIONAL LAKE IN CENTRAL ILLINOIS1

Johnson Sauk Trail Lake remains highly eutrophic, even though the watershed has long been returned to an undisturbed condition with permanent vegetative cover and with little or no land disturbance in the watershed. Internal regeneration of nutrients has been identified as the major source of nutrients to the lake. Lake destratification, selective harvesting and removal of weeds, and control of algal blooms using chelated copper sulfate application followed by potassium permanganate application have all been chosen as management techniques for improving water quality conditions in the lake. These in-lake techniques are considered not as palliative measures, but as necessary tools in enhancing the lake's water quality characteristics.     

Spatial Heterogeneity of Water Quality in a Highly Degraded Tropical Freshwater Ecosystem

Awareness of environmental heterogeneity in ecosystems is critical for management and conservation. We used the Xochimilco freshwater system to describe the relationship between heterogeneity and human activities. This tropical aquatic ecosystem south of Mexico City is comprised of a network of interconnected canals and lakes that are influenced by agricultural and urban activities. Environmental heterogeneity was characterized by spatially extensive surveys within four regions of Xochimilco during rainy and dry seasons over 2 years. These surveys revealed a heterogeneous system that was shallow (1.1 m, SD = 0.4 ), warm (17°C, SD = 2.9), well oxygenated (5.0 mg l⁻¹, SD = 3), turbid (45.7 NTU SD = 26.96), and extremely nutrient-rich (NO₃–N = 15.9 mg l⁻¹, SD=13.7; NH₄–N = 2.88 mg l⁻¹, SD = 4.24; and PO₄–P =  8.3 mg l⁻¹, SD = 2.4). Most of the variables were not significantly different between years, but did differ between seasons, suggesting a dynamic system within a span of a year but with a high resilience over longer periods of time. Maps were produced using interpolations to describe distributions of all variables. There was no correlation between individual variables and land use. Consequently, we searched for relationships using all variables together by generating a combined water quality index. Significant differences in the index were apparent among the four regions. Index values also differed within individual region and individual water bodies (e.g., within canals), indicating that Xochimilco has high local heterogeneity. Using this index on a map helped to relate water quality to human activities and provides a simple and clear tool for managers and policymakers.     

ESTIMATING EVAPORATION FROM UTAH'S GREAT SALT LAKE USING THERMAL INFRARED SATELLITE IMAGERY1

ABSTRACT: Water surface temperatures can be obtained from satellite thermal remote sensing. Landsat and other satellites sense emitted thermal infrared radiation on a regular basis over much of the earth's surface. Evaporation is accomplished by the net transport of mass from the water surface to the atmosphere. The evaporative transfer predominantly determines the water surface temperature. Hence, there should be good correlations between evaporation and surface temperatures. Previous investigations on Utah Lake with satellite-derived temperatures and pan- and model-derived evaporation values have produced good correlations. However, more study was required with additional satellite data and evaporation measurements for saltwater conditions. The applicability of this method for estimating evaporation on Utah's Great Salt Lake was of particular interest at this time because of the unprecedented rise of this terminal lake. Satellite thermal data and evaporation data from four different years were obtained for the Great Salt Lake and the surrounding region. More than 350 correlation and linear regression analyses were performed on the temperature and evaporation data. The lake salt concentrations were also factored into the analyses in several different ways. The correlation results were generally very good and a methodology for using satellite-derived water surface temperatures along with salt concentrations was developed to estimate evaporation.