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本实验采集太湖梅梁湾底泥及上覆水,在保持底泥表面完整的前提下在实验室中建立湖泊生态系统模拟装置,探索太湖底泥中蓝藻种群的复苏规律经60d光照升温培养,显微观察蓝藻复苏细胞,测定底泥和上覆水中的色素含量.结果表明,在室内模拟条件下,太湖底泥蓝藻复苏初始时主要以2-8个细胞的小群体存在,其细胞直径为7.2-7.8μm,大于夏季的藻群体中的细胞直径(4.8-6μm).底泥蓝藻的复苏过程与环境温度变化密切相关.蓝藻在水体温度达到14℃时开始少量进入水柱中,在环境温度升至18-20℃之间时大量进入水中,为水华形成提供了种源.底泥蓝藻的最佳复苏温度(18-20℃)高于非蓝藻的复苏温度(14-18℃),高温对蓝藻复苏更为有利 相似文献
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太湖冬季底泥中活体藻类的检测 总被引:11,自引:2,他引:11
2002年冬从太湖梅梁湾采集柱状底泥,取三段进行直接镜检和用MA培养基进行光照培养.镜检发现表层(0-3cm)底泥中有多种藻类细胞,中层(10-13cm)底泥的藻类细胞种类明显减少,下层(20-23cm)底泥中没有发现藻类细胞.底泥培养的结果与之有相似的趋势,但得到的活体藻类细胞的种类相应减少.培养3个月后得到在外观和群落结构上与夏季水华相似的群落.结果表明底泥中的微囊藻和小环藻在太湖底泥中具有良好的适应性,占有明显的优势地位,底泥可以作为水华蓝藻的越冬场所和来年水华的种源. 相似文献
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2018年10月-2019年10月对巢湖西湖心水体浮游藻类群落结构以及水体和底泥蓝藻生物量进行了月度调查.结果表明:巢湖西湖心浮游藻类的主要优势种属为微囊藻属、席藻属、十字藻、卵形隐藻和鱼腥藻属.蓝藻优势种属在5-10月为微囊藻属,11-12月为鱼腥藻属,1-4月为席藻属.巢湖水体和底泥蓝藻生物量峰值分别出现在9月和2月,水体蓝藻的衰亡下沉会导致底泥蓝藻生物量的上升.巢湖蓝藻主要分布在水体,底泥蓝藻生物量相对较低,单位面积水柱与底泥蓝藻生物量6月的比值大于100,在11-3月相对较低,最低值小于2.底泥蓝藻主要分布在底泥表层0~2 cm.通过安装原位捕获器,监测了蓝藻在西巢湖湖心水柱和底泥中的垂直迁移过程和通量.结果表明:11月和2月蓝藻有明显从水柱向底泥迁移的过程;底泥蓝藻全年向水体的静态迁移量都很低,而动态迁移在11月和6月出现两个峰值,主要受底泥蓝藻生物量和再悬浮的影响.本研究结果表明削减巢湖西湖心底泥种源的最佳时期为10月至来年2月,但是由于底泥蓝藻生物量远远小于水柱蓝藻生物量,底泥蓝藻向水体复苏迁移的通量也较低,即使削减了底泥种源,也不能有效降低水体蓝藻生物量. 相似文献
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气温对太湖蓝藻复苏和休眠进程的影响 总被引:6,自引:4,他引:2
利用2005 2014年每日的卫星数据、气象站和浮标站观测资料研究复苏期和休眠期的平均气温、稳定通过界限温度初终日、周有效积温与太湖蓝藻休眠和复苏时间的关系,探讨气温是否是影响蓝藻休眠和复苏时间进程的关键因子.分析结果显示:太湖蓝藻复苏早晚与春季(3 5月)气温密切相关,春季气温越高,蓝藻复苏时间越早;太湖蓝藻休眠时间与秋、冬季(11次年1月)气温密切相关,秋、冬季气温越高,蓝藻休眠时间越晚.此外根据分析结果发现,太湖首次出现蓝藻水华的时间一般是气温稳定通过9℃初日之后的1个月左右,但上一周期的休眠与下一周期的复苏之间气温异常偏高会导致蓝藻水华首次出现时间早于稳定通过9℃初日;最后一次蓝藻水华出现时间与气温稳定通过4℃的终日相近;在复苏期,湖水中的叶绿素a浓度随周有效积温变化而变化,二者相关系数为0.9. 相似文献
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湖泊底泥疏浚对沉积物再悬浮及营养盐负荷影响的模拟 总被引:5,自引:2,他引:3
选取太湖梅梁湾污染底泥为研究对象,利用沉积物再悬浮发生装置,通过室内模拟实验研究太湖夏季常规风情下底泥疏浚对沉积物再悬浮及上覆水营养盐动态变化的影响.结果表明,在模拟的风情扰动过程结束时(5 h),扰动过程未疏浚与疏浚处理水柱总悬浮颗粒物(TSS)含量变化差异显著,未疏浚对照水柱TSS含量是初始值的7.7倍,而疏浚水柱TSS在第2 h达到峰值,为初始值的3.8倍;未疏浚水柱TSS含量沉降过程最初1 h迅速降低了84.0%,而疏浚水柱TSS含量在沉降3 h后趋于平衡.伴随着沉积物的再悬浮过程,疏浚与未疏浚对照水柱中TP含量均在第5 h达到最大,分别增加负荷78.6和92.2 mg/m2.就短时效而言,底泥疏浚后沉积物的再悬浮过程显著受到抑制,并能够显著地减小沉积物再悬浮过程中溶解性磷酸盐的释放;但对水柱中总磷、总氮、铵氮、硝酸盐和亚硝酸盐含量变化影响较小. 相似文献
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太湖水华成因及控制途径初探 总被引:45,自引:12,他引:45
1990年8~12月对太湖水华9次调查表明,水华主要由漂浮性蓝藻—微囊藻组成,夏季SE风时其漂移集聚是西北湖区形成严重水华的主要原因。这种漂移使得藻类所含营养物逆吞吐流方向传输,形成了一种“生物营养滤器”,加速了太湖尤其是西北湖区的富营养化进程。太湖外源N、P负荷量分别为12.0和0.85g/(m~2·a),足以引起富营养化;表层5cm底泥中含丰富的N、P,其释放也成为湖水中部分营养的来源。因2~8月藻类总生物量的增长基本遵守Logistic方程dN/dt=N·r(1—N/K),故对藻类控制可从N、r入手,即通过收获藻类达到控制藻类总量和营养输出的双重功效;提高水位增加非光合层厚度,有效地降低水柱中藻类生产力;建立有水生植被的水质保护区也是一种局部藻类控制方法。 相似文献
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太湖蓝藻水华的预防、预测和预警的理论与实践 总被引:67,自引:21,他引:46
综述了蓝藻水华预防、预测预警的重要意义及其理论与技术体系.基于作者所提出的将蓝藻水华形成分为休眠、复苏、生长和上浮聚集形成水华的"四阶段理论",以及太湖蓝藻越冬、春季复苏和水华形成的时空规律,提出了太湖蓝藻水华的预防理念.综述了国内外蓝藻水华形成与预测研究进展,阐述了蓝藻水华形成关键过程的主导生态因子及其阈值:确定了水华蓝藻越冬的空间分布与生命特征,利用室内模拟实验和野外原位观测与捕捉,得到了蓝藻春季复苏的室内和野外温度阈值分别为14℃和9℃,发现了蓝藻复苏量与有效生理积温呈正相关的基本规律;初步揭示了水华蓝藻生长竞争优势形成的生物学与生态学机理以及光利用策略,利用细胞分裂频率法测定了夏季太湖水华蓝藻的原位生长速率为0.2-0.4;确定了在不同水文气象条件下,水华蓝藻在水体中垂直分布和在不同湖区之间输移的基本格局,发现藻类在水体中各层间百分含量的变异系数随着风浪的增大而减小,进一步证明了蓝藻水华形成是在适当水文气象要素驱动下,已经成为优势种群的水华蓝藻在湖体中空间位置的改变而引起的.建立了太湖蓝藻水华预测模型和工作流程,在2007年和2008年在太湖实施了未来3d的蓝藻水华预测预警,预测分析了2008年全年太湖蓝藻水华情势.对预测结果的回顾性评估与分析表明,目前已有的理论研究结果和预测工作流程可以对太湖蓝藻水华发生概率、发生地点和强度进行预测,预测准确率达到60%-80%.此外,还提出了未来蓝藻水华预测的研究方向. 相似文献
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贵州红枫湖越冬藻类的空间分布与实验室复苏实验 总被引:1,自引:0,他引:1
本文选取贵州省红枫湖这一典型的亚深水型湖泊作为研究对象,在8个代表性湖区开展了为期一年的表层水体藻类浮游植物分布的月定量监测,并在4个采样点采集新鲜沉积物进行了越冬藻类赋存与复苏模拟实验研究.研究表明,红枫湖表层水体藻类种群密度蓝藻绿藻>硅藻>甲藻,蓝藻为优势门类,水体藻类种群密度秋季初期最高,其次是春季初期和夏季,具有明显的季节性演化特征.水体中越冬藻类以蓝藻为主,其次是硅藻和绿藻,水深对水体中藻类的种群密度及组成没有显著影响.沉积物中越冬藻类以硅藻为主,基本不含蓝藻.模拟实验表明,水体中的光照条件对藻类的复苏和生长有重要影响,温度和沉积物中藻类的种群密度与组成同样影响藻类的复苏. 相似文献
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底泥和藻体对太湖湖泛的诱发及水体致黑物的供应潜力 总被引:8,自引:6,他引:2
为确定底泥和藻体在太湖湖泛形成过程中对致黑物形成的贡献,采用室内模拟系统,研究底泥、蓝藻以及底泥+蓝藻3种处理,模拟湖水在不同厌氧程度下湖泛特征参数(黑度、铁及硫形态)的变化,分析不同处理以及受不同聚藻程度影响区(八房港、焦山)底泥对湖泛的诱发作用及致黑物供给潜力.结果表明,各处理组诱发太湖湖泛发生的难易顺序为:底泥+蓝藻处理组底泥处理组蓝藻处理组.底泥+蓝藻处理组中Fe2+浓度为蓝藻处理组的11~94倍,其平均浓度为后者的33倍,而底泥+蓝藻处理组中还原性硫浓度为其他处理组的2~56倍.研究还发现,聚藻区底泥较非聚藻区更易发生湖泛,这是由于聚藻区底泥富集了更高浓度的铁、硫等还原性物质,但厌氧处理与非厌氧处理在诱发湖泛发生的风险差异不明显.以上结果证实,厌氧环境下低价铁硫供应潜力的差异是决定湖泛发生的主要物质来源,加强对聚藻区底泥及蓝藻的控制是有效防控太湖湖泛发生的主要措施之一. 相似文献
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Our view of how water quality effects ecosystems of the Great Barrier Reef (GBR) is largely framed by observed or expected responses of large benthic organisms (corals, algae, seagrasses) to enhanced levels of dissolved nutrients, sediments and other pollutants in reef waters. In the case of nutrients, however, benthic organisms and communities are largely responding to materials which have cycled through and been transformed by pelagic communities dominated by micro-algae (phytoplankton), protozoa, flagellates and bacteria. Because GBR waters are characterised by high ambient light intensities and water temperatures, inputs of nutrients from both internal and external sources are rapidly taken up and converted to organic matter in inter-reefal waters. Phytoplankton growth, pelagic grazing and remineralisation rates are very rapid. Dominant phytoplankton species in GBR waters have in situ growth rates which range from approximately 1 to several doublings per day. To a first approximation, phytoplankton communities and their constituent nutrient content turn over on a daily basis. Relative abundances of dissolved nutrient species strongly indicate N limitation of new biomass formation. Direct ((15)N) and indirect ((14)C) estimates of N demand by phytoplankton indicate dissolved inorganic N pools have turnover times on the order of hours to days. Turnover times for inorganic phosphorus in the water column range from hours to weeks. Because of the rapid assimilation of nutrients by plankton communities, biological responses in benthic communities to changed water quality are more likely driven (at several ecological levels) by organic matter derived from pelagic primary production than by dissolved nutrient stocks alone. 相似文献
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Seasonal variations in the trophic structure of phyto-and zooplankton communities in lakes in different trophic states 总被引:2,自引:0,他引:2
A number of environmental factors are important in regulating the trophic structure of plankton. Increased nutrient supply results in an explosive development of small algae and herbivorous zooplankton. In the eutrophic lakes (Greifensee, Hallwilersee) several algal community collapses occur each year as a consequence of the grazing habit of the zooplankton, although only the grazing phase in May/June results in a ‘clear water period’. Vertical mixing influences the zooplankton community by reactivating the resting stages of predatory copepods. Predation phases can only be observed in lake Lucerne, where the hypolimnion ist deep and aerobic. Well balanced relationships between the different trophic levels are restricted to the phases with growth limiting conditions. 相似文献
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On 26 October, 1977, the tanker Tsesis grounded in the Swedish archipelago, 65 km south of Stockholm (northern Baltic proper, 59°N, 18°E). The Tsesis carried 17575 t of No. 5 fuel oil. The total spill was estimated as being somewhat more than 1000 t, of which about 600–700 t were recovered, thus leaving about 300 t in the environment. The spill occurred only about 5 km east of the Askö Laboratory, a marine ecological station, which made a relatively fast sampling response possible. The effects on the pelagic ecosystem were studied for 1 month following the spill. Severe effects were recorded only in the immediate vicinity of the wreck where zooplankton biomass declined substantially during the first few days after the spill. Within 5 days the zooplankton biomass was re-established. Oil contamination of zooplankton was recorded for over 3 weeks. It is suggested that an increased phytoplankton biomass and primary production in the impacted area was due to decreased zooplankton grazing rates. Increased bacterial numbers and the oil degradation pattern indicated a rapid bacterial degradation of hydrocarbons in the water column. Sediment traps positioned in the area demonstrated the importance of sedimentation as a pathway for removal of oil from the water column. During the second week after the spill, 0.7% of sedimented material was petroleum hydrocarbons. Using sediment trap data, a total sedimentation of 30–60 t of oil was estimated in the impacted area (42 km2). This corresponds to 10–15% of the unrecovered oil. 相似文献
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鲫(Carassius auratus)是我国各类淡水水体的优势鱼类之一.作为底栖杂食性鱼类,一方面,鲫可以通过排泄和扰动沉积物影响湖泊营养和光照水平,通过"上行效应"促进浮游植物生长;另一方面,鲫也可以捕食浮游动物,通过"下行控制"影响藻类生长以及营养盐循环.对于浅水湖泊,两种途径对于生态系统影响的相对重要性仍有待研究.本研究设计了一个两因素户外中宇宙实验,通过在沉积物表面添加隔网的方式,比较两种情况下(能、否接触沉积物),鲫对水体浊度、营养盐和浮游生物生物量的影响.实验在16个大型钢化玻璃桶(400 L)中进行,持续36 d(2019年8月6日—9月11日).研究结果表明:1)在能接触沉积物的条件下,鲫显著促进了沉积物再悬浮,表现为水体的总悬浮物(TSS)和无机悬浮物(ISS)浓度大幅升高;水体的光衰减系数(Kd)增加,总氮(TN)和总磷(TP)浓度明显升高; 2)在不能接触沉积物的条件下,鲫对水体悬浮物(TSS和ISS)浓度和Kd的影响不明显,但是显著降低了水体TN和TP浓度; 3)在两种情况下,鲫对浮游植物叶绿素a浓度以及浮游动物生物量的影响均不显著.本研究表明鲫只有在能够接触沉积物的条件下,才会显著提高水体浊度和营养水平.因此,在缺乏沉水植被的浅水湖泊中,鲫扰动沉积物产生的"上行效应"可能是其对生态系统产生负面影响的主要途径. 相似文献
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Rodrigo Sinistro María Laura Snchez María Cristina Marinone Irina Izaguirre 《Limnologica》2007,37(1):88-99
An experimental study using mesocosms was conducted in the main shallow lake of a temperate wetland (Otamendi Natural Reserve, Argentina) to analyse the impact of zooplankton on phytoplankton and the microbial assemblages. The lake is characterised by the presence of a fluctuating cover of floating macrophytes, whose shading effects shape the phytoplakton community and the ecosystem functioning, which was absent during the study period. The experiment was run in situ using polyethylene bags, comparing treatments with and without zooplankton. The cascade effect of zooplankton on phytoplankton and the lower levels of the microbial food web (ciliates, heterotrophic nanoflagellates (HNF) and picoplankton) were analysed.A significant zooplankton grazing on the nano-phytoplankton fraction (3–30 μm) was observed. Conversely, large algae (filamentous cyanobacteria, colonial chlorophytes and large diatoms) increased in all mesocosms until day 10, suggesting that they were not actively grazed by zooplankton during this period. However, from day 10 until day 17 this fraction decreased in the enclosures with mesozooplankton, probably due to an increase in the abundance of large herbivores.The results of the experiment would also indicate a trophic cascade effect on the lower levels of the microbial community. In the treatment where zooplankton was removed, the abundance of ciliates followed the same increasing pattern as the abundance of HNF, but with a time lag in its response. In the enclosures without zooplankton, HNF remained relatively constant throughout the experiment, whereas ciliates strongly decrease during the last week. Total picoplankton abundance increased in the enclosures with mesozooplankton, thus supporting the existence of a four-link trophic cascade (copepods–microzooplankton–HNF–picoplankton). Zooplankton composition changed significantly from the beginning until the end of the experiment; cyclopoid nauplii and rotifers were notoriously dominant at t0, whereas 10 days later the community showed a more equitable proportion of cyclopoids, calanoids, nauplii, cladocerans and rotifers. 相似文献
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Patterns of zooplankton–phytoplankton interactions in subtropical lakes of the Southern Hemisphere may deviate from those established for north-temperate lakes. We tested the responses of phytoplankton growth to different community structures of zooplankton and nutrient enrichment in a subtropical Australian reservoir for the prediction of potential outcomes of lake biomanipulation. Two zooplankton communities were created in lake enclosures over 4 weeks: a rotifer-dominated community developed in the presence of planktivorous fish (Hypseleotris spp.) and a Ceriodaphnia-dominated community developed in the absence of fish. Biomass gradients of both communities were established in 20 L containers and several separate containers received no additions (controls) or were enriched with nitrogen and/or phosphorus. The growth rate of total phytoplankton significantly increased in response to nutrient enrichment, indicating nutrient limitation. Most phytoplankton taxa were not markedly affected by grazing of either zooplankton community. However, both communities had significant stimulatory effects on the growth of inedible chlorophytes. The ability of zooplankton grazing to negatively affect phytoplankton growth during the summer was counteracted regardless of zooplankton community structure, possibly by nutrients regenerated by zooplankton. We hypothesise that in the subtropical system studied, changes in food web nutrient recycling may be more important for the outcome of biomanipulation than grazing impacts. 相似文献