沉水植被构建对上海辰山植物园景观湖水质的影响

以辰山植物园景观湖为研究对象,研究了景观湖建成初期沉水植物群落构建对水体水质因子的影响;并应用相关性分析(correlation analysis)和主成分分析(principal components analysis)对各水质和生态因子之间的相互关系进行了研究。结果表明,景观湖沉水植被建成1年后,水体水质处于Ⅲ类,其中叶绿素a含量5.48±1.930μg/L、总氮1.40±0.136mg/L、总磷0.080±0.015 mg/L、透明度108±20 cm、高锰酸盐指数5.50±1.26 mg/L;除高锰酸盐指数(CODMn)外,其他水质指标均较构建前有显著改善;并且景观湖水质显著优于外河道补充水源水质。相关性分析表明,景观湖水体叶绿素a含量与N、P营养盐呈显著正相关,但却与水温呈极显著负相关,这显示了草型景观湖水质的显著特征;主成分分析显示,第一主成分包含硝态氮、亚硝态氮、总磷、活性磷、叶绿素、水温、透明度和pH等变量,第二主成分包括高锰酸盐指数和氨氮等变量;第一主成分中的水质参数可作为辰山植物园景观湖后续水生态管理中的主要监测对象;此外,主成分分析还显示TP对水体叶绿素的增加具有很高正权重。     

CASS＋人工湿地工艺处理城镇污水工程实例

本文论述了成都市某小流域末端污水处理站的工艺流程,介绍了主要的构筑物和设备及其参数。该污水处理站属于成都市2009年小流域治污工程,采用CASS＋人工湿地工艺处理城镇污水。运行稳定后,且在进水稳定下出水氨氮和CODCr达到《城镇污水处理站污染物排放标准》（GB18918-2002）中的一级A类标准。     

大别山区诸佛庵镇深水河山洪灾害分析

综合下垫面条件、气象与水文信息,对皖西大别山区的诸佛庵镇“05．9”小流域暴雨,进行暴雨重现期和洪水过程分析计算。结合灾害特征,探讨其成因。在小流域风险洪水预估的基础上,从防灾减灾的角度提出对策性建议。     

Watershed Nitrogen and Mercury Geochemical Fluxes Integrate Landscape Factors in Long-term Research Watersheds at Acadia National Park, Maine, USA

This paper is an overview of this special issue devoted to watershed research in Acadia National Park (Acadia NP). The papers address components of an integrated research program on two upland watersheds at Acadia NP, USA (44° 20′ N latitude; 68° 15′ E longitude). These watersheds were instrumented in 1998 to provide a long-term foundation for regional ecological and watershed research. The research was initiated as part of EPA/NPS PRIMENet (Park Research and Intensive Monitoring of Ecosystems Network), a system of UV-monitoring stations and long-term watershed research sites located in US national parks. The initial goals at Acadia NP were to address research questions about mercury, acid rain, and nitrogen saturation developed from prior research. The project design was based on natural differences in forests and soils induced by an intense wildfire in one watershed in 1947. There is no evidence of fire in the reference watershed for several hundred years. We are testing hypotheses about controls on surface water chemistry, and bioavailability of contaminants in the contrasting watersheds. The unburned 47-ha Hadlock Brook watershed is 70% spruce-fir mature conifer forest. In contrast, burned 32-ha Cadillac Brook watershed, 4 km northeast of the Hadlock watershed, is 20% regenerating mixed northern hardwoods and 60% shrub/rocky balds. Differences in atmospheric deposition are controlled primarily by forest stand composition and age. The watersheds are gauged and have water chemistry stations at 122 m (Cadillac) and 137 m (Hadlock); watershed maximum elevations are 468 and 380 m, respectively. The stream water chemistry patterns reflect, in part, the legacy of the intense fire, which, in turn, controls differences in forest vegetation and soil characteristics. These factors result in higher nitrogen and mercury flux from the unburned watershed, reflecting differences in atmospheric deposition, contrasting ecosystem pools of nitrogen and mercury, and inferred differences in internal cycling and bioavailabilty.     

Accumulation and distribution of90Sr and137Cs in birch in the zone affected by liquid discharge from the Beloyarskaya Nuclear Power Plant

The data are presented that concern the accumulation and distribution of artificial radionuclides (⁹⁰Sr and¹³⁷Cs) in the aboveground organs of birch growing in the vicinity of the Beloyarskaya Nuclear Power Plant (NPP) in the permanently inundated part of the Ol'khovka swamp, on its banks periodically flooded with water, and in watershed areas not influenced by the swamp (control). Concentrations of both radionuclides in birch trees from the swamp and its banks were several times as high as in trees from the watershed. The distribution of⁹⁰Sr in birch trunk proved to be acropetal. Trees growing on the inundated part of the swamp and on dry land significantly differed in the distribution of¹³⁷Cs. The factors controlling the distribution and accumulation of both radionuclides in birch trees growing in these areas are discussed.     

半导体器件失效案例统计与综合分析

电子元器件是电子产品最基本的组成部分,而半导体器件通常又是关键与核心器件;半导体器件失效数占电子元器件总失效数的一半以上。本文针对半导体器件的失效案例进行筛选、汇总,按照失效类别、失效模式和失效原因进行分类统计,并对统计数据进行分析;其结果可以为从事元器件质量管理、元器件研制、采购和整机设计人员在元器件研制、采购、试验、选用和使用等全过程控制半导体器件失效提供重要的参考数据。     

小流域面源污染治理与评估模型研究进展

随着社会经济的发展,我国水体污染状况日益严重,如何有效控制水体污染已经成为环境保护工作的重点。本文介绍了面源污染小流域水体环境的影响因素,提出流域性污染治理的对策,并对小流域污染治理的国内外研究进展进行了初步的总结,如小流域地形影响、污染构成及流失规律、模型的开发与应用等,进而为我国的水体环境污染治理工作提供经验借鉴及技术参考。     

The Role of Riparian Vegetation in Protecting and Improving Chemical Water Quality in Streams1

Dosskey, Michael G., Philippe Vidon, Noel P. Gurwick, Craig J. Allan, Tim P. Duval, and Richard Lowrance, 2010. The Role of Riparian Vegetation in Protecting and Improving Chemical Water Quality in Streams. Journal of the American Water Resources Association (JAWRA) 46(2):261-277. DOI: 10.1111/j.1752-1688.2010.00419.x Abstract: We review the research literature and summarize the major processes by which riparian vegetation influences chemical water quality in streams, as well as how these processes vary among vegetation types, and discuss how these processes respond to removal and restoration of riparian vegetation and thereby determine the timing and level of response in stream water quality. Our emphasis is on the role that riparian vegetation plays in protecting streams from nonpoint source pollutants and in improving the quality of degraded stream water. Riparian vegetation influences stream water chemistry through diverse processes including direct chemical uptake and indirect influences such as by supply of organic matter to soils and channels, modification of water movement, and stabilization of soil. Some processes are more strongly expressed under certain site conditions, such as denitrification where groundwater is shallow, and by certain kinds of vegetation, such as channel stabilization by large wood and nutrient uptake by faster-growing species. Whether stream chemistry can be managed effectively through deliberate selection and management of vegetation type, however, remains uncertain because few studies have been conducted on broad suites of processes that may include compensating or reinforcing interactions. Scant research has focused directly on the response of stream water chemistry to the loss of riparian vegetation or its restoration. Our analysis suggests that the level and time frame of a response to restoration depends strongly on the degree and time frame of vegetation loss. Legacy effects of past vegetation can continue to influence water quality for many years or decades and control the potential level and timing of water quality improvement after vegetation is restored. Through the collective action of many processes, vegetation exerts substantial influence over the well-documented effect that riparian zones have on stream water quality. However, the degree to which stream water quality can be managed through the management of riparian vegetation remains to be clarified. An understanding of the underlying processes is important for effectively using vegetation condition as an indicator of water quality protection and for accurately gauging prospects for water quality improvement through restoration of permanent vegetation.     

Effect of Watershed Subdivision and Filter Width on SWAT Simulation of a Coastal Plain Watershed1

Cho, Jaepil, Richard R. Lowrance, David D. Bosch, Timothy C. Strickland, Younggu Her, and George Vellidis, 2010. Effect of Watershed Subdivision and Filter Width on SWAT Simulation of a Coastal Plain Watershed. Journal of the American Water Resources Association (JAWRA) 46(3):586-602. DOI: 10.1111/j.1752-1688.2010.00436.x Abstract: The Soil and Water Assessment Tool (SWAT) does not fully simulate riparian buffers, but has a simple filter function that is responsive to filter strip width (FILTERW). The objectives of this study were to (1) evaluate SWAT hydrology and water quality response to changes in watershed subdivision levels and different FILTERW configurations and (2) provide guidance for selecting appropriate watershed subdivision for model runs that include the riparian buffer feature through the FILTERW parameter. Watershed subdivision level is controlled by the critical source area (CSA) which defines the minimum drainage area required to form the origin of a stream. SWAT was calibrated on a 15.7 km² subdrainage within the Little River Experimental Watershed, Georgia. The calibrated parameter set was applied to 32 watershed configurations consisting of four FILTERW representations for each of eight CSA levels. Streamflow predictions were stable regardless of watershed subdivision and FILTERW configuration. Predicted sediment and nutrient loads from upland areas decreased as CSA increased when spatial variations of riparian buffers are considered. Sediment and nutrient yield at the watershed outlet was responsive to different combinations of CSA and FILTERW depending on selected in-stream processes. CSA ranges which provide stable sediment and nutrient yields at the watershed outlet was suggested for avoiding significant modifications in selected parameter set.