完全均匀混合质量平衡水质模型在滇池中的应用

介绍了完全均匀混合假设下以质量平衡为基础的湖泊水质模型,运用滇池的实测数据对模型进行了参数率定、验证,给出了模型在滇池水质预测中的应用实测,最后讨论了模型的几个假设条件对滇池的适应性。实例研究表明,该模型可适用于滇池水质有机污染长期浓度预测。      

滇池水体和沉积物中营养盐的分布特征

在滇池外海不同方位选取6个采样点,研究了水质现状,沉积物Eh,pH,总氮,总磷以及间隙水重金属的剖面分布特征。结果表明,滇池水体仍属富营养化状态。在氧化表层下,Eh随沉积深度的增加迅速降低,沉积物深层为还原状态。pH在沉积物剖面变化不大,为7 0～8 5。滇池沉积物含有丰富的营养物质,总氮和总磷最高质量分数分别为8 67和3 46g kg。剖面分布表明,沉积物表层总氮和总磷含量远高于底层,在表层0～10cm含量随深度增加而迅速降低。重金属元素在水-土界面的浓度梯度为沉积物向水体的扩散提供了条件。不同采样点相比,位于昆明市附近的S6点沉积物内负荷较大。在外源减少的情况下,沉积物内负荷可能在一定时间内成为控制滇池水质的主导因子。      

石盘丘小流域不同土地利用方式下土壤氮磷流失形态及通量

为了解三峡库区小流域不同土地利用方式下土壤氮、磷流失特征,为农业非点源污染防控提供科学依据;采用田间试验的方法,研究了三峡库区石盘丘小流域水田、旱坡地、林地、柑橘园和菜地这5种土地利用方式下地表径流不同形态氮、磷流失浓度与通量的特征.结果表明：全氮流失通量的顺序为水田[17.73 kg·（hm²·a）^-1] > 柑橘园[4.86 kg·（hm²·a）^-1] > 旱坡地[4.33 kg·（hm²·a）^-1] > 菜地[4.00 kg·（hm²·a）^-1] > 林地[2.41 kg·（hm²·a）^-1];全磷流失通量的顺序为菜地[4.97 kg·（hm²·a）^-1] > 柑橘园[1.87 kg·（hm²·a）^-1] > 水田[0.93 kg·（hm²·a）^-1] > 林地[0.27 kg·（hm²·a）^-1] > 旱坡地[0.19 kg·（hm²·a）^-1];5种土地利用方式下氮、磷流失主要集中在降雨频繁的4~5月,占全年氮、磷流失总负荷的53.80%~96.52%和56.03%~87.78%;氮流失主要以硝态氮（16.16%~52.70%）的形态流失,全氮流失通量与径流量呈现出显著正相关关系（R²=0.9826）;在菜地中颗粒磷是磷流失的主要形态（83.30%）,但在其他土地利用方式中表现不显著.不同土地利用方式下不同形态氮、磷流失存在显著差异,其中菜地应针对强降雨情况下颗粒磷流失的问题采取措施,水田应避免在降雨集中时期施肥;科学施肥和合理地土地利用方式配置是治理小流域农业非点源污染的重要途径.     

滇池流域土地利用景观空间格局对水质的影响

选用综合水质评价方法,对滇池流域进行水质评价。选取斑块数量（NP）、斑块密度（PD）、最大斑块指数（LPI）、最大形状指数（LSI）,作为表征景观空间格局的参数,来分析流域优势斑块对水质的影响。对水质评价结果与景观指数进行相关性分析得出：居民点及工矿用地斑块数量越多、形状越不规则,有利于延缓水质状况的恶化;耕地斑块越大,越集中,本身产生的面源污染浓度就越高,而流经耕地的径流中的污染物浓度则会因大斑块的吸附过滤作用而降低;林地斑块密度越大,对污染物的截留纳污作用就越大,而斑块越大,可能产生局限性,导致未流经林地的污染物直接进入河流而影响水质。     

2008年滇池流域水环境承载力评估

自20世纪70年代以来,随着经济迅猛发展以及人口的快速增长,滇池流域的水环境问题日益突出. 为深入了解造成当前水环境问题的根本原因,以水资源承载力和水环境承载力作为广义水环境承载力的基础进行综合分析,并且利用水资源供需平衡和水资源承载压力度反映水资源承载力,利用水环境承载率反映水环境承载力. 结果表明:滇池流域TN和TP的水环境承载率分别为0677和0355,处于超载状态,是导致滇池流域严重富营养化的主要原因;水资源承载压力度为145,远大于供需平衡,同样也处于超载状态,实际水资源盈亏为-59 037×104 m3,缺失严重. 因此,滇池流域水质型和资源型缺水问题共同存在.      

滇池内湖滨带沉积物中重金属形态分析

采用BCR3步分级提取法测定了滇池内湖滨带沉积物中4种重金属(Pb、Cd、Cu和Zn)不同形态的含量,初步评估了这4种重金属的生物有效性.结果表明,Cd和Zn主要以可提取态存在(即弱酸溶解态、可还原态和可氧化态),而Pb和Cu均以残渣态为主要存在形式.通过计算可提取态含量所占总量百分量大小,可知各金属的生物有效性大小排序为:Zn(53.06%)>Cd(50.84%)>Cu(34.62%)> Pb(28.65%).沉积物中总有机碳(TOC)与各金属不同形态间的相关性分析表明,可氧化态重金属与有机碳结合的趋势远大于弱酸溶解态和可还原态.表层沉积物中可提取态重金属的空间分布特征明显表现为草海>外海,除Cu外,大部分样点的可提取态Pb、Cd和Zn含量均随采样深度增加而减少.     

Assessment of a large watershed in Brazil using Emergy Evaluation and Geographical Information System

Humanity's future depends on the preservation of natural ecosystems that supply resources and absorb pollutants. Rural and urban productions are currently based on chemical products made from petroleum, which are responsible for high negative impacts on the Biosphere. In order to prevent those impacts, efficient public policies seeking for sustainable development are necessary. Aiming to assess the load on the environment (considering the gratuitous contributions of natural systems—a donor's perspective) due to human-dominated process, a scientific tool called Emergy Evaluation has been applied in different production systems, including crops and farms. However, there is still a lack of emergy studies in the context of watersheds, probably due to the difficulty of collecting raw data. The present work aims to carry out an assessment of Mogi-Guaçu and Pardo watershed, through the combined use of Emergy Evaluation and Geographical Information System. The agricultural and natural land uses were considered, while urban areas were excluded. Emergy flows (expressed in seJ ha⁻¹ yr⁻¹) obtained for all agricultural and natural land uses were expanded for the whole watershed and the emergy indices were calculated. The results show that the watershed has: low renewability (%R = 32%); low capture of natural resources through high external economic investment (EYR = 1.86); low dependence on natural resources (EIR = 1.16); and moderate load on the environment (ELR = 2.08). Considering a scenario where sugar-cane crops, orchards and pasture areas are converted from conventional to organic management, watershed's emergy performance improved, reaching a new renewability of 38%, but it is still not enough to be considered sustainable.     

Role of rural solid waste management in non-point source pollution control of Dianchi Lake catchments, China

In recent years, with control of the main municipal and industrial point pollution sources and implementation of cleaning for some inner pollution sources in the water body, the discharge of point source pollution decreased gradually, while non-point source pollution has become increasingly distressing in Dianchi Lake catchments. As one of the major targets in non-point source pollution control, an integrated solid waste controlling strategy combined with a technological solution and management system was proposed and implemented based on the waste disposal situation and characteristics of rural solid waste in the demonstration area. As the key technology in rural solid waste treatment, both centralized plant-scale composting and a dispersed farmer-operated waste treating system showed promise in rendering timely benefits in efficiency, large handling capacity, high quality of the end product, as well as good economic return. Problems encountered during multi-substrates co-composting such as pathogens, high moisture content, asynchronism in the decomposition of different substrates, and low quality of the end product can all be tackled. 92.5% of solid waste was collected in the demonstration area, while the treating and recycling ratio reached 87.9%, which prevented 32.2 t nitrogen and 3.9 t phosphorus per year from entering the water body of Dianchi Lake after implementation of the project.     

Watershed development in India. 1. Biophysical and societal impacts

This paper recommends a revision of watershed development policy in India in relation to the planning of development interventions involving agricultural intensification and rainwater harvesting following biophysical and societal impact studies carried out on two watershed development projects in Karnataka. A need for changes in policy has arisen in response to progressive catchments closure at the basin level and declining volumes of water flowing into village level reservoirs (known locally as tanks). Flow reductions have occurred largely as a result of increased agricultural intensification over the past 10–15 years. Field levelling, field bund construction, soil water conservation measures, farm ponds, the increase in areas under horticulture and forestry and the increased abstraction and use of groundwater for irrigation are all contributing factors to reduced flows. Planning methodologies and approaches, which may have been appropriate 20 years ago for planning water harvesting within watershed development projects, are no longer appropriate today. New planning approaches are required which (1) take account of these changed flow conditions and (2) are also able to take account of externalities, which occur when actions of some affect the livelihoods of others who have no control or influence over such activities and which (3) contribute to the maintenance of agreed minimum downstream flows for environmental and other purposes.

滇池周边浅层地下水硝酸盐来源及转化过程识别

明确硝酸盐的主要来源及转化过程对地下水氮污染防治和水资源开发利用具有重要意义.为了探明滇池周边浅层地下水中硝酸盐污染现状及来源,于2020年雨季（10月）和2021年旱季（4月）在滇池周边共采集73个浅层地下水样,运用水化学和氮氧同位素（δ¹⁵N-NO₃^-、δ¹⁸O-NO₃^-）识别浅层地下水中硝酸盐的空间分布、来源及转化过程,并结合同位素混合模型（SIAR）定量评价不同来源氮对浅层地下水硝酸盐的贡献.结果表明,旱季浅层地下水中有40.5%的采样点ρ（NO₃^--N）超过地下水质量标准（GB/T 14848）Ⅲ类水质规定的20 mg·L^-1,雨季超过47.2%的采样点ρ（NO₃^--N）超过20 mg·L^-1.氮氧同位素和SIAR模型分析结果证明了土壤有机氮、化肥氮、粪肥和污水氮是浅层地下水硝酸盐的主要来源,以上氮源对旱季浅层地下水中硝酸盐的贡献率分别为13.9%、11.8%和66.5%,对雨季的贡献率分别为33.7%、31.1%和25.9%,而大气氮沉降贡献率仅为8.5%,对该区浅层地下水中硝酸盐来源贡献较小.硝化作用是旱季浅层地下水中硝态氮转化的主导过程,雨季以反硝化作用为主,且反硝化作用雨季比旱季明显.