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1.
随着经济社会的快速发展和进步,我国湖库水体富营养化情况越来越严重.卫星遥感在水体营养状态监测方面具有重要潜力,但基于卫星遥感的全国范围内湖库水体营养状态监测和分析方面还鲜有研究.本文基于2018夏季的MODIS卫星遥感数据生产FUI指数产品,构建基于FUI水色指数的湖库营养状态评价方法,监测全国范围内144个重点湖库水体的营养状态等级.结果表明:贫营养、中营养、富营养的湖库比例分别为16%、24%、60%;营养状态在空间上分布不均匀,总体上呈现东高西低的现象;东北山地与平原和东部平原湖区以富营养状态水体为主;西部湖库水体以贫到中营养状态为主,尤其是青藏高原湖区贫营养比例比较高;海拔和地表温度等自然因素与工业点源和农业面源污染等人为因素是湖库营养状态的重要影响因素. 相似文献
2.
Ash Kumar Rai 《湖泊科学》1998,10(S1):181-201
Harnessing the natural resources is one of the basis of natural economy in developing countries. The wise use of such resources is very important to sustain the balance between immediate benefits and maintenance of the ecosystem. In Phewa, Begnas and Rupa lakes of Pokhara Valley, plankton feeding fish farming in net cage,enclosure and open water stocking is one of the effective example of natural resources utilisation which sustains a number of households in surrounding lakes for economic activities. These lakes are also used for drinking water, hydroelectricity, irrigation and recreation etc. However, the understanding of trophic status of the lakes is very important for long term sustainable use of the lakes in harmony with human activities. Here, we present the trophic status of three lakes of Pokhara Valley and discuss the impacts of human and natural activities on the trophic status of the lake. The study shows that heavy rain fall in the valley during monsoon is one of the strongest natural forces which flush out the accumulated nutrients from the lakes and migrate the eutrophication processes. Recommendations for sustainable use of lake water have also been discussed. 相似文献
3.
三十年来长江中下游湖泊富营养化状况变迁及其影响因素 总被引:9,自引:5,他引:4
为弄清长江中下游通江/历史通江湖泊富营养化现状、成因及修复策略,对该区域27个大型湖泊和水库开展了4个季度的水质调查,并结合部分湖泊1988-1992年及2008年两个时段富营养化调查成果,分析近30年来长江中下游地区大型湖泊富营养化关键指标变化的特征及其驱动因素.结果表明,目前该区域绝大多数湖泊处于富营养水平,较1980s有明显加重,浮游植物叶绿素a及总磷是最主要的营养状态指数贡献因子;湖泊的富营养化状况与湖泊的江湖连通状况、换水周期等流动性状况、渔业养殖及管理、流域纳污、治理强度等人类活动方式和强度密切相关;与历史调查结果相比,氮、磷的增幅相对较小,而有机质污染程度明显加重、浮游植物叶绿素a浓度大幅增高,表明营养盐之外的其他因素,如水文节律的变化、江湖阻隔、不合理的渔业养殖活动等,对该区域湖泊的富营养化问题加剧、浮游植物生产力增高起到更为重要的作用.因此,从治理途径和策略上来看,增加湖泊的流通性、恢复部分湖泊的自然水文波动节律、优化湖泊渔业管理、提升湖泊流域营养盐的有效截留能力、实施湖泊生态修复工程是控制长江中下游湖泊富营养化、提升区域湖泊生态质量的关键. 相似文献
4.
水生高等植物-浮游植物关系和湖泊营养状态 总被引:29,自引:5,他引:24
本文根据中国一些湖泊的资料,从湖泊营养化角度分析了水生高等植物的生物量,分布和优势种以及浮游植物,透明度和湖泊营养状态的关系,表明高等植物和浮游藻类这两种初级生产者的生产在浅水湖泊中呈负相关,并反映在水质指标和湖泊营养状态下,同是,简要讨论了光限制,营养供给和生化抑制作用在浮游植物与水生高等植物关系中的作用。 相似文献
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The objective of this study is the assessment of the typology and the trophic relevant water quality parameters in two Mediterranean lakes (Lake Ziros and Lake Kastoria) under the view of the WFD. Lake types were identified based on characteristics specified in Annex II of the WFD, while trophic indexes (OECD, TSI Carlson) were used in order to assess their trophic status. A modified TSI index appropriate for warmer lakes was also applied. According to our results, Lake Kastoria is classified as eutrophic lake with a tendency to hypertrophication while Lake Ziros is a mesotrophic ecosystem with clear signals of eutrophication. Both ecosystems are considered “at risk” of not fulfilling the WFD environmental objectives due to the existence of certain anthropogenic pressures. 相似文献
7.
湖泊富营养化已经成为水资源领域的研究焦点,是水环境领域面临的长期严峻挑战.为探明干旱半干旱区域湖泊营养状态,以典型岱海水体为例,利用2019—2020年6次野外实测数据为基础,针对Sentinel_2A和Landsat_8 OLI遥感数据,基于营养状态指数TSISDD与色度角之间的相关关系,建立了岱海水体营养状态评估模型,并利用1986—2020年遥感影像数据,得到了长时间序列的水体营养状态.结果表明:(1)本文建立的营养状态评估模型,根据精度检验结果显示模型精度较好,决定系数(R2)为0.74,均方根误差(RMSE)为3.66,平均绝对百分比误差(MAPE)为4.84%.(2)将算法应用到时间序列MSI、TM、ETM+和OLI数据,得到了岱海水体1986—2020年的营养状态动态特征.结果表明,岱海水体面积逐年减少,且多数时间处在轻度富营养化状态.水体富营养化现象大体上从边缘逐渐向湖中心趋于缓和,离岸边越近富营养化现象越严重,通常趋向湖中心以中营养为主,整体上贫营养化现象极少.(3)岱海营养状态时空变化与气温、风速和降水量等气候因子的相关性并不显著,对其解释率为13%.气候因子对营养状态的月变化影响显著,对其解释率为93%. 相似文献
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《Acta Geochimica》2021,(4)
Currently,lakes and artificial reservoirs are increasingly threatened by eutrophication,which is the result of the combined action of many natural and anthropogenic factors.In the past,the effect of nutrient load on the trophic state of water bodies has attracted much attention,while few studies have addressed the effect of hydrological characteristics.Therefore,to reveal the coupling effects of hydrological characteristics and nutrient load in sediments on the trophic state of water bodies,this study collected relevant data from 36 lakes and reservoirs across China.Pearson correlation analysis showed that trophic level index was positively and significantly correlated with nutrient load in sediments and hydraulic retention time,while it was negatively correlated with mean depth and hydraulic load.The principal component analysis showed that the nutrient load was the first major component that influenced the trophic state of water bodies,followed by the mean depth and hydraulic retention time.Eutrophication was prone to occur in water bodies with mean depth less than 7 m and hydraulic retention time greater than 14 d,and the trophic level index regression equation with hydrological characteristics and nutrient load in sediments was derived by multiple regression analysis.This study revealed that the trophic state of water bodies influenced by both nutrient load and hydrological characteristics.It provides a new idea to reduce the occurrence of eutrophication in reservoirs by using the artificial hydrological regulation capacity of reservoirs. 相似文献
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长江中下游浅水湖泊富营养化发生机制与控制途径初探 总被引:191,自引:22,他引:169
长江中下游地区是我国淡水湖泊比较集中的地区。该地区绝大多数湖泊为浅水湖泊,所有的城郊湖泊都已经富营养化,其他湖泊的营养状况均为中营养-富营养,处于富营养化的发展中,这些湖泊富营养化的原因同流域上的人类活动有很大的关系。一方面,工业,农业和城市生活污水正源源不断地向湖泊中排放。另一方面,人类通过湖泊围垦、湖岸忖砌,水产养殖等破坏自然生态环境,减少营养盐输出途径。国际上对于浅水湖泊富营养化治理的经验表明,即使流域上的外源污染排放降到历史最低点,湖泊富营养化问题依然突出,其原因与浅水湖泊底泥所造成的内源污染有关。动力作用导致底泥悬浮,,影响底泥中营养盐的释放,也影响水下光照和初级生产力。控制浅水湖泊富营养化,除了进行外源性营养盐控制之外,还必须进行湖内内源营养盐的治理。治理内源营养盐的有效途径是恢复水生植被,控制底泥动力悬浮与营养盐释放。而要进行水生植被恢复,必须进行湖泊生态系统退化机制及生态修复的实验研究。 相似文献
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综合营养状态指数(TLI)在夏季长江中下游湖库评价中的局限及改进意见 总被引:1,自引:0,他引:1
综合营养状态指数(TLI)在中国湖库富营养化评价中应用非常广泛.对于该指数的各分项指标,基于叶绿素a的评估结果是富营养化风险的直接体现,是最终指示;而基于理化指标(总氮、总磷、透明度和高锰酸盐指数)的评估结果是间接指示.如果两者TLI评估结果存在显著差异,则说明基于理化参数的TLI评估结果低估或者高估了实际富营养化水平和相关风险.本文针对长江中下游湖库的基于水质理化指标和基于叶绿素a的TLI结果是否匹配的问题开展了调查分析.结果表明,对于非通江浅水湖泊而言,基于总氮、总磷、高锰酸盐指数的TLI评估结果均低估了富营养化水平和相关风险;对于通江浅水湖泊而言,基于总氮、总磷和透明度的TLI评估结果高估了富营养化水平和相关风险,而基于高锰酸盐指数的结果低估了富营养化水平;对于深水水库,基于总氮的TLI指数评估结果高估了富营养化水平,而基于总磷、透明度和高锰酸盐指数的结果低估了富营养化水平.上述水质理化指标和叶绿素a评估结果不匹配的原因为以下两点:第一,部分物理化学指标失去了对富营养化风险(叶绿素a)的指示意义,如通江浅水湖泊的总氮、总磷、透明度和高锰酸盐指数以及深水湖泊的总氮;第二,部分富营养化理化指标和叶绿素a原有关系发生错位,比如对于深水湖泊总磷对叶绿素a的响应比TLI指数构建所采用的关系更加敏感.针对TLI理化指标评估在长江中下游湖库应用中存在的问题提出如下改进建议:1)结合长时间序列历史数据,基于分位数回归等方法构建特定湖泊的叶绿素a和理化参数的响应关系,开发“一湖一策”的评估公式;2)根据换水周期和湖泊面积水深比对进行湖泊分类,建立特定湖泊类型的叶绿素a和理化参数的响应关系,构建“一类一策”的评估公式;3)在富营养化评估结果中应分别量化富营养化状态参数(营养盐水平)和富营养化风险参数(叶绿素a)以及两者比值,但生物指标是富营养化评估的最终指示.现阶段我国富营养化评价和管理多为“全国一策”,可能很难满足经济高效的管理需求.因此,本研究所建议和综述的“一类一策”和“一湖一策”的湖泊富营养化评估方法对未来的湖泊生态管理可能具有重要意义. 相似文献
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N. A. Gashkina 《Water Resources》2011,38(3):352-371
The results of large-scale studies of water chemistry in small lakes in European Russia were used to characterize the distributions
and ratios of biogenic elements and organic matter from the viewpoint of the zonal peculiarities of their turnover rate. Latitudinal
regularities were identified in the limiting of lake production with respect to major biogenic elements. A classification
of lakes is proposed, where the lakes are regarded as a system based on the percent distribution of organic carbon, nitrogen
and phosphorus forms, as well as the trophic status and the totality of indices characterizing the origin of OM and the extent
of its transformation. 相似文献
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B. V. Adamovich T. V. Zhukova T. M. Mikheeva R. Z. Kovalevskaya E. V. Luk’yanova 《Water Resources》2016,43(5):809-817
Variations of the trophic status of lakes Batorino, Myastro, and Naroch were analyzed over a long period of 1978–2013. The lakes form a system of interconnected water bodies with a wide range of trophic states. In the period under consideration, the trophic conditions in the lakes varied from highly eutrophic (Lake Batorino) to oligotrophic (Lake Naroch), making it possible to analyze the long-term changes in the trophic state of the lakes with the use of different variants of evaluating the Carlson index (trophic state index, TSI), to assess the relationship between the three versions of the index with one another, with phytoplankton biomass, and with hydroecological characteristics, such as the concentrations of total N, seston, and organic matter and biochemical oxygen demand. The possibility to evaluate the index by other characteristics, including phytoplankton biomass, was also considered. 相似文献
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基于多个环境变量、以等权或者加权平均法获得的综合营养状态指数(Carlson指数:TSIc;修正后的Carlson指数:TSImc;综合营养状态指数:TLIc;湖库营养状态指数:EIc)得分是当前评价湖泊营养水平的主要依据,其值计算时先要获得基于单个环境变量的营养状态指数分值。若基于总氮(TN)、总磷(TP)和透明度(SD)等的单个理化指标与基于叶绿素a(Chl.a)的营养状态指数得分间存在显著差异,表明依据理化指标的评估结果低估或者高估湖泊的实际营养水平。长江下游分布大量的小型浅水富营养化湖泊,但基于理化指标的评估结果是否会误判湖泊的实际富营养化水平的研究很少。本研究以长江下游的14个浅水富营养化湖泊为对象,于2019 2020年按照季度采集水样并测定水环境因子,分析基于理化指标和基于Chl.a的各营养状态指数(TSI、TSIm、TLI和EI)得分间的差异。结果表明,基于SD的TSI、TSIm、TLI和EI的年均得分均显著高于基于Chl.a的相应营养状态指数的年均值;除TSI(TP)vs.TSI(Chl.a)外,基于TP与基于Chl.a的其他营养指数的年均得分间均有显著性差异;仅TL... 相似文献
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为探究“十三五”期间武汉市湖泊水质变化特征及规律,分析当前武汉市湖泊水环境的主要问题及成因,为武汉市水生态环境保护“十四五”规划提供科学支撑,以武汉市166个湖泊为研究对象,根据武汉市环境监测中心2015-2019年对各个湖泊的监测数据,采用水质综合污染指数、富营养化状态评价、动态度分析等方法,对武汉市湖泊水环境进行综合评价.结果表明:1)2015-2019年武汉市湖泊水质总体好转,2019年全市湖泊综合污染指数较2015年下降7.74%,多数湖泊营养状态呈现稳中向好趋势,但湖泊水质较难实现持续改善.2)武汉市湖泊主要超标污染物总磷、氨氮、化学需氧量和高锰酸盐指数平均质量浓度在2015-2019年间均呈下降趋势,但2019年有47%湖泊总磷浓度劣于Ⅳ类评价标准,磷元素是制约湖泊水质的主要因素.3)2015-2019年武汉市中心城区湖泊综合污染指数下降,湖泊富营养化状态好转,但青山北湖、南湖等湖泊综合污染指数较高,排口排污、底泥内源污染是影响中心城区湖泊水质的主要因素.新城区湖泊水质改善仍面临一定压力,东西湖水系重度富营养化湖泊数量增多,后湖水系湖泊综合污染指数上升,农业面源、工业生产对新城区湖泊水质影响较大,湖泊破碎化导致的自净能力降低也是影响湖泊水质的重要因素. 相似文献
15.
广东长潭水库富营养化与浮游植物分布特征 总被引:2,自引:1,他引:1
为掌握梅州市长潭水库富营养化状态与浮游植物分布特征,为控制藻类水华暴发提供科学依据,2011年10月至2012年7月,在长潭水库关键断面选取10个监测点,测定水体理化特征、浮游植物种类、丰度等指标,采用营养状态指数(TLI)和Shannon-Wiener多样性指数法对水质污染现状进行评价,并分析浮游植物类群分布特征.结果表明:长潭水库水体富营养状态在4、10和12月处于中营养级,7月份处于富营养级,营养指数从库区中游上游逐渐降低;观测期间共检出浮游植物4门11科16属,通过丰度比较,发现长潭水库以蓝绿藻为优势种,并且季节变化明显,总体表现为7月 >4月 >10月 >12月;藻类多样性指数分析显示,水库水体污染水平为中度,中游和库区(除7月)为轻度污染,与综合营养指数结果一致;长潭水库污染源调查分析结果表明,该水库主要为氮、磷污染,污染源主要为上游禽畜养殖废水. 相似文献
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This paper is a review of research works concerning the nutrient transportation, transformation and exchange between water, sediment and biota in the lakes from the middle and lower reaches of the Yangtze River conducted in the context of project entitled “The Processes and Mechanism of Lake Eutrophication in Middle and Lower Reaches of Yangtze River”. All the lakes from this area are shallow lakes. According to the typical lake site research, the lakes from the middle and lower reaches of Yangtze River have a higher baseline of nutrition in the history. Normally the trophic status of these lakes can be categorized into medium-trophic or eutrophic Human activities have been enhanced during the last decades, which speed up the lake eutrophic process. Lake eutrophication control needs to reduce not only the external nutrient inputs from watershed but also the internal loading from the sediments. Investigations revealed that the lake sediments in this area are considerablly high in nutrition in which at most about 30% of phosphorus exists in the form of bio-available in the sediment. The surface sediment will exert great effects on the nutrient exchange between water-sediment interface via adsorption and release of nutrient. The nutrient release from the sediment in these shallow lakes is mainly in two ways, i.e. in the undisturbed condition the nutrient is released through diffusion created by the nutrient gradient from sediment to overlying water; whereas in disturbed condition, the nutrient release is determined by the hydrodynamic forcing intensity and the sediment resuspension. Metallic elements such as the iron, manganese and aluminium and the aerobic-anaerobic ambience will affect the release of nutrients. The disturbed release will increase the total nutrients in the water column significantly in the short period. At the beginning of sediment resuspension, the dissolved nutrient concentration will increase. This increase will be damped if the ferric oxide and aluminium are rich in sediment because of the adsorption and flocculation. This means that the lakes have capability of eliminating the nutrient loadings. Investigations for the lakes from middle and down stream of Yangtze River have suggested that most lakes have the self-cleaning capability. Dredging the control of the internal loading, therefore, is only applicable to the small lakes or undisturbed bays which normally are situated nearby the city or town and rich in organic materials in the sediment. In addition, the strong reduction condition and weak aeration of these lakes and bays make these small lakes and bays release much more bio-available nutrient and without much self-eliminating capability. Moreover, eutrophication induced algal bloom in these lakes will change the pH of water, which further induces the increase in the nutrient release. In turn, the increase in nutrient release promotes the growth of phytoplankton and results in severe algal bloom. For the heavily polluted water, research suggests that the biomass of bacteria and alkaline phosphatase activity will be higher corresponding to the higher concentration of nutrients, which accelerates the nutrient recycling between water, sediment and biota. Quick recycling of nutrient, in turn, promotes the production and biomass growth of microorganism and leads to more severe eutrophication. Further research work should focus on the nutrient transformation mechanism and the effects of microbial loop on the eutrophication.
相似文献18.
This paper is a review of research works concerning the nutrient transportation, transformation and exchange between water, sediment and biota in the lakes from the middle and lower reaches of the Yangtze River conducted in the context of project entitled "The Processes and Mechanism of Lake Eutrophication in Middle and Lower Reaches of Yangtze River". All the lakes from this area are shallow lakes. According to the typical lake site research, the lakes from the middle and lower reaches of Yangtze River have a higher baseline of nutrition in the history. Normally the trophic status of these lakes can be categorized into medium-trophic or eutrophic. Human activities have been enhanced during the last decades, which speed up the lake eutrophic process. Lake eutrophication control needs to reduce not only the external nutrient inputs from watershed but also the internal loading from the sediments. Investigations revealed that the lake sediments in this area are considerablly high in nutrition in which at most about 30% of phosphorus exists in the form of bio-available in the sediment. The surface sediment will exert great effects on the nutrient exchange between water-sediment interface via adsorption and release of nutrient. The nutrient release from the sediment in these shallow lakes is mainly in two ways, i.e. in the undisturbed condition the nutrient is released through diffusion created by the nutrient gradient from sediment to overlying water; whereas in disturbed condition, the nutrient release is determined by the hydrodynamic forcing intensity and the sediment resuspension. Metallic elements such as the iron, manganese and aluminium and the aerobic-anaerobic ambience will affect the release of nutrients. The disturbed release will increase the total nutrients in the water column significantly in the short period. At the beginning of sediment resuspension, the dissolved nutrient concentration will increase. This increase will be damped if the ferric oxide and aluminium are rich in sediment because of the adsorption and flocculation. This means that the lakes have capability of eliminating the nutrient loadings. Investigations for the lakes from middle and down stream of Yangtze River have suggested that most lakes have the self-cleaning capability. Dredging the control of the internal loading, therefore, is only applicable to the small lakes or undisturbed bays which normally are situated nearby the city or town and rich in organic materials in the sediment. In addition, the strong reduction condition and weak aeration of these lakes and bays make these small lakes and bays release much more bio-available nutrient and without much self-eliminating capability. Moreover, eutrophication induced algal bloom in these lakes will change the pH of water, which further induces the increase in the nutrient release. In turn, the increase in nutrient release promotes the growth of phytoplankton and results in severe algal bloom. For the heavily polluted water, research suggests that the biomass of bacteria and alkaline phosphatase activity will be higher corresponding to the higher concentration of nutrients, which accelerates the nutrient recycling between water, sediment and biota. Quick recycling of nutrient, in turn, promotes the production and biomass growth of microorganism and leads to more severe eutrophication. Further research work should focus on the nutrient transformation mechanism and the effects of microbial loop on the eutrophication. 相似文献
19.
湖北长湖富营养化状况及时空变化(2012-2013年) 总被引:4,自引:1,他引:3
为评估长湖水体富营养化程度,2012-2013年分4个季度对全湖区20个采样点的物理、化学和生物要素进行监测,在评价水质现状的基础上采用综合营养状况指数法和浮游植物细胞丰度指数法综合评价水体营养状况,并应用典型相关分析(CCA)方法揭示水体富营养化状况与湖泊理化要素之间的典型相关性.结果显示:4个季节长湖全湖区的水质均处于地表水IV类~劣V类水标准;综合营养状态指数值在49.54~82.55之间,浮游植物细胞丰度在2.88×106~61.73×106cells/L之间,均显示其处于富营养化状态;长湖富营养化状况的分布呈现一定的时空差异性;CCA分析显示,长湖理化要素变量可解释68.6%的水体富营养化状况变量的变异,影响其富营养化状况的主要理化因素有水体总磷、总氮、溶解氧、亚硝态氮、硝态氮浓度,水深和沉积物总磷、总氮含量.长湖水体富营养化主要是由于外源的磷污染,其次是氮污染,富营养化最严重的夏、秋季浮游植物的生长主要受氮营养限制,而冬、春季则部分受磷营养限制,部分属于过渡类型.因此,建议大力削减围网/围栏养殖量,同时考虑结合水生植物栽种等生态工程建设措施以降低长湖水体发生严重富营养化的风险,并进一步改善长湖的水质现状. 相似文献
20.
近年来云南高原湖泊面临富营养化、渔业活动增强等多重环境压力的叠加影响,对湖泊的有效治理与生态修复急需对多重压力下生态系统的响应模式进行系统了解.现有研究表明在系统生产力和捕食压力的不同配置下,湖泊系统主要组成(如浮游动物)的响应特征可能出现差异且捕食压力可能随营养水平的变化而改变,目前对云南湖泊生态系统的研究主要集中于单一环境压力下的生态响应.本研究以目前分别处于重富营养和中-贫营养水平的滇池和抚仙湖为研究对象,应用湖泊沉积物记录进行多指标分析,探讨受外来鱼类影响下两个大型湖泊浮游动物长期响应模式的异同.通过象鼻溞生物量与个体大小等指标,重建了近百年来滇池与抚仙湖典型浮游动物的变化历史,结果表明随着湖泊生产力水平(如沉积物色素生产量)的增加,2个湖泊中象鼻溞生物量显著增加,同时物种相对组成出现明显变化(如Bosmina longispina被B.longirostris取代),指示湖泊上行效应对浮游动物的控制作用.同时象鼻溞的生物量、壳长与触角长度的变化在1960s与1980s有明显降低的趋势,与同期外来鱼类(如银鱼)引入与渔业产量增加的时间一致.进一步应用多变量回归分析与方差分解方法来定量评价上行与下行效应对象鼻溞生物量变化的驱动强度,结果表明富营养化(沉积物色素)和捕食作用(象鼻溞壳长)对浮游动物长期变化的驱动强度比较相似(分别解释了生物量变化的77.25%和83.59%),然而在滇池下行效应对象鼻溞生物量的独立影响比在贫营养的抚仙湖中更强(分别为15.46%和10.39%),上行效应对象鼻溞生物量的影响在抚仙湖要明显强于滇池(分别为69.74%和19.67%),而在滇池上行与下行效应的相互作用强度明显强于抚仙湖(分别为42.12%和3.46%).结果表明随着湖泊营养水平的升高,浮游动物的生物量在2个湖泊中均显著增加,而外来鱼类(如太湖新银鱼)的引入和经济鱼类数量的增加加剧了对浮游动物的捕食压力,造成了浮游动物的生物量降低和个体减小.但在快速富营养化的滇池,对浮游动物的捕食压力随营养水平的变化出现较强的依赖性,而在总体处于中-贫营养水平的抚仙湖中此相互作用较弱.结果表明在不同营养水平的大型湖泊中,营养水平的变化幅度可以导致鱼类捕食压力的差异性变化,指示了对鱼类捕食压力的评价和浮游动物长期变化的特征分析需要考虑湖泊的营养水平与富营养化过程的差异.总之,富营养化和外来鱼类的引入导致了高原湖泊生态系统的快速响应与结构变化,因此对高原湖泊的生态修复需要考虑湖泊营养水平对生态系统结构与食物链作用的影响. 相似文献