千岛湖浮游动物的群落结构

研究了贫－中营养型的大型,深水湖泊－－浙江千岛湖浮游动物的群落结构,包括种类组成,种群动态,现存量及群落多样性指数。在1a的研究中,共发现139种浮游动物（27种原生动物,70种轮虫,26种枝角类和16种桡足类）。根据年平均密度,各类浮游动物的优势种分别为褶累枝(Epistylis plicatilie),螺形龟甲轮虫9Keratella cochlearis),透明蚤（Daphnia hyalina)和一种中剑水蚤（Mesocyclops notius)。轮虫和枝角类群落多样性指数随着水体透明度的增大呈下降的趋势;采样站变异下,枝角类群落多样性指数与其种类数和密度呈显著的正相关关系;月份变异下,桡足类群落多样性指数与其密度呈显著的正相关关系。     

南四湖浮游动物群落结构特征及其与环境因子的关系

为探讨南四湖浮游动物多样性特征及其与水质的相关性,于2012年夏季(7月)和冬季(12月)对南四湖浮游动物的群落结构进行了系统研究,结合历史数据,分析了南四湖浮游动物群落的多样性特征和时间变化。共采集到浮游动物163种,其中,轮虫78种,原生动物65种,枝角类17种,桡足类3种。夏季记录浮游动物种类数(141种)高于冬季(105种)。从四个湖区来看,微山湖浮游动物种数最多(102种),其次是南阳湖(95种)和昭阳湖(80种),独山湖(73种)较少。南四湖浮游动物全年平均密度为2 192 ind/L,平均生物量为2.27 mg/L。除原生动物外,其他三类浮游动物夏季的平均密度和生物量都高于冬季。采用丰富度指数、Shannon-Wiener指数和均匀度指数对浮游动物多样性进行了评价,结果均显示,南四湖浮游动物多样性夏季高于冬季。通过回归分析发现,总氮是影响浮游动物密度的主要因素,总氮和水温是影响浮游动物生物量的主要因素,p H和电导率是影响浮游动物多样性的主要因素。     

浙江千岛湖浮游动物群落多样性研究

1999年1～12月对浙江千岛湖浮游动物的群落结构,包括密度多样性和生物量多样性进行了 系统研究。轮虫类的多样性指数最高,并且当湖泊在一定的营养水平范围内（贫营养型向中 营养型过渡）时,轮虫的密度多样性与湖泊的营养水平呈现相同的变化趋势。以时间和空间 为参照,对千岛湖两种浮游动物多样性指数与群落因素之间进行了相关分析,得到相关关系 如下：月变化密度多样性＝-0.922+4.521×密度均匀度,n=12, r=0.872, p<0.001;生物量多样性=1.99-0.348×透明生物量,n=12, r=-0.868, p<0.01;水平变化密度多样性＝2.35+0.008×种类数, n=10, r=0.672, p<0.05;生物量多样性=2.88-1.739×生物量优势度, n=10, r=-0.826, p<0.01。     

江苏常熟尚湖浮游动物种群初步研究

2003年3～5月对尚湖浮游动物种群结构特征和生物多样性进行了初步研究。观察到尚湖浮游动物93种,其中原生动物38种,轮虫27种,枝角类18种,桡足类10种。采用Shannon-Wiener多样性指数公式,对浮游动物的物种多样性指数、密度多样性指数和生物量多样性指数进行了分析。     

三疣梭子蟹两种养殖模式浮游动物调查

于2012年6-12月,在宁波市象山县东盛水产养殖有限公司对主养三疣梭子蟹池塘两种混养模式（模式Ⅰ：三疣梭子蟹与日本对虾、黑鲷、菲律宾蛤仔混养;模式Ⅱ：三疣梭子蟹与日本对虾、黑鲷混养）浮游动物进行了调查与比较。结果显示：共检出浮游动物13属19种,其中,原生动物3属3种;轮虫2属5种;枝角类2属3种;桡足类6属8种。浮游动物平均密度模式Ⅰ（370 ind./L）〉模式Ⅱ（209 ind./L）;平均生物量模式Ⅰ（17.974 mg/L）〈模式Ⅱ（18.102 mg/L）。Margalef指数为0.22~0.81;Shannon-Wiener指数为1.28~3.03;Pielou均匀度指数为0.54~0.96,均值都是模式Ⅰ〉模式Ⅱ。     

The impact of zooplankton status on the management of Lake Kinneret (Israel)

Monthly averages of standing stock wet biomass of zooplankton in Lake Kinneret (Israel) varied between 11 and 76 g m^–2 during 1969–1981, with the exception of two months. Averaged contributions of different groups were: Cladocera 58%, Copepoda 35% and Rotifera 7%. Total standing crop wet biomass is highest during January–June, averages varied between 35 and 50 g m^–2, and decreases during summer–fall (23–36 g m^–2). The winter biomass of Cladocera fluctuated between 22 and 35 g m^–2 and dropped to a range of 9–23 g m^–2 in summer, whereas copepod biomass varied very little around an average of 18 g (ww) m^–2 with the exception of low values from April to June. The stock biomass of Rotifera is relatively high during winter floods season (December-March) whilst in summer it is very low.Young stages of fish in Lake Kinneret feed mostly on zooplankton and zoobenthic forms. The most abundant fish in the Kinneret ecosystem, Mirogrex terraesanctae terraesanctae, also feed on zooplankton at the adult stage throughout the year, and herbivorous fish consume zooplankton during the summer when lake plankton resources are limited.The summer ecosystem of Lake Kinneret is characterised as a steady state type, in which the impact of the zooplankton-chain is of great importance. Increase of predation pressure on zooplankton by fish can disequilibrate the balanced trophic relations existing between nannoplankton production and zooplankton grazing capacity. Such a situation can lead to organics accumulation as nannoplankton blooms, resulting in water quality deterioration. Management options aimed at preventing collapse of zooplankton populations are discussed.     

鹊山引黄水库浮游动物时空分布特征

根据2012年5—10月对济南鹊山水库及库前沉沙条渠内的采样调查结果, 分析了浮游动物的种类和密度的时空分布。结果共检出浮游动物24属41种, 其中种数最多的是轮虫类, 其次为纤毛虫类, 枝角类和桡足类最少。条渠内检出的优势种数明显多于水库, 但两处优势种的时间变化特征相似。条渠和水库内均出现的优势种有沟钟虫、钟形钟虫、壶状臂尾轮虫、尾突臂尾轮虫、裂痕龟纹轮虫、象鼻溞、汤匙华哲水蚤。采样期间条渠和水库的Shannon-wiener多样性指数(H')分别在2.59—2.96和2.74—2.94范围内波动, Pielou均匀度指数(J’)分别在0.88—0.99和0.83—0.92范围内波动。根据条渠和水库内共19个采样点的四大类浮游动物密度的聚类分析结果, 研究区域可分为条渠中前端、条渠末端-水库入口及水库其他范围3个区域, 不同区域的浮游动物群落结构有显著差异, 表明条渠的沉沙过程对浮游动物群落有较大的影响。     

北部湾近岸海域浮游动物群落结构特征及季节变化

2017年3月(枯水期)、7月(丰水期)和10月(平水期)分别对北部湾近岸海域44个站位的浮游动物进行了调查。结果共检出浮游动物251种和浮游幼体24类,其中枯水期138种(类),丰水期134种(类),平水期191种(类),分属河口低盐、近岸暖温、近岸暖水和外海暖水4个生态类群。优势种9种,其中枯水期以原生动物占绝对优势,丰水期以枝角类、桡足类和浮游幼体类占优势,平水期以十足类和浮游幼体类占优势。浮游动物丰度年均值为789.95个/m~3,呈现出枯水期(1540.19个/m~3)明显高于平水期(457.58个/m~3)和丰水期(372.08个/m~3)的季节变化特征;浮游动物生物量年均值为252.40 mg/m~3,生物量的季节变化与丰度变化不一致,平水期生物量(385.01 mg/m~3)明显高于枯水期(221.41 mg/m~3)和丰水期(150.78 mg/m~3)。多样性指数平水期最高(3.16),丰水期(2.35)次之,枯水期(2.22)最低。枯水期和丰水期北部湾近岸海域浮游动物生物量和丰度水平分布特征基本呈现自河口近岸海域向外海递增的趋势,平水期浮游动物生物量与丰度的空间分布较为均匀。浮游动物的种类组成结构以及优势种的演替对浮游动物的生物量和丰度季节变化有着重要的决定作用。径流导致的悬浮物、营养盐等的变化可能是决定北部湾近岸海域浮游动物生物量和丰度空间分布的主要因素。研究还表明与其他海湾相比,北部湾近岸海域浮游动物群落结构趋于小型化,需加大关注。     

浙江千岛湖桡足类的群落结构

1999年1－12月,研究了贫－中营养型的大型深水湖泊－浙江千岛湖浮游桡足类的群落结构,包括其种类组成、现存量动态及群落多样性。在一年的研究中,共观察到16种桡足类（5种哲水蚤、1种猛水蚤和10种剑水蚤）。根据各种桡足类（桡足幼体＋成体）的年平均密度,哲水蚤的优势种为右突新镖水蚤（Neodiaptomus schmack-eri)和球状许水蚤（Schmackeria forbesi);剑水蚤的优势种为一种中剑水蚤（Mesocyclops notius)和近邻剑水蚤（Cyclops vicinus)。桡足类群落平均密度46.81个／L,生物量0.126mg/L,物种多样性指数1.54。桡足类现存量的季节变化为夏＞秋＞冬＞春,8月份密度达98.50个／L,生物量0.333mg/L;5月份密度仅10.70个／L,生物量0.017mg/L。水平变化以Ⅱ号站现存量为最高,密度达80.10个／L,生物量0.289mg/L;V号站的密度最低,仅29.80个／L;Ⅳ号站生物量最低,0.066mg/L。多样性指数以I站为最高3.21,Ⅸ站最低,仅0.85。桡足类群落多样性随着水体透明度的增大呈下降的趋势。     

五大连池浮游动物群落结构的时空分布特征

基于2011—2013年五大连池的调查,对浮游动物群落结构时空分布特征进行分析,探讨重点放养鱼类之一鳙Aristichthys nobilis的合理放养量。结果表明,五大连池浮游动物4类82种(含未定种);主要优势种集中于原生动物和轮虫,有恩氏筒壳虫Tintinnidium entzii、纵长异尾轮虫Trichocerca elongate等,大型浮游动物中仅剑水蚤Cyclops sp.、无节幼体Nauplii形成优势;密度、生物量总计为3794.98ind/L和2.4558mg/L;多样性指数H'、J、d均值分别为2.15、0.7和0.98;浮游动物群落时空差异显著,五池密度、生物量、多样性、均匀度较高,二池(P2)、三池(P3)相似且次于五池;另外,二池(P2)、三池(P3)浮游动物的密度、生物量、多样性均呈现夏季高于春秋季;根据结果获得五大连池鳙的合理放养量为5.71×105尾。研究可为五大连池生境保护和渔业资源的可持续利用提供科学依据。     

Mean individual dry weight and length-weight regressions of some zooplankton of Lake Kariba

Individual dry weights of various crustacean zooplankton in Lake Kariba were determined. All the zooplankters were collected from pelagic waters. Regression equations relating dry weight to body length were computed for those species or groups in which size classes could be separated: Bosmina longirostris, Ceriodaphnia cornuta, and copepod copepodites and adults. The mean individual dry weights obtained for most of these zooplankters are similar to those reported in other studies.     

Diel vertical distribution of zooplankton in Lake Naivasha,Kenya

Diurnal and diel vertical distribution of limnetic zooplankton species in relation to temperature and dissolved oxygen profiles was examined at a central station in Lake Naivasha. During calm days thermal stratification developed gradually from late morning to reach maximum formation at mid-day. Dissolved oxygen concentrations showed similar vertical profiles to temperature. These stratifications were, however, short lived and were broken up in late afternoons by the wind induced poly-holomictic nature of the lake. During the day most zooplankters aggregate at the top 3–4 metre zone of the water column coincident with maximum photosynthetic activity. The pattern of diel vertical distribution of zooplankton in Lake Naivasha is undefinedly even. The absence of significant diel changes in the distribution of the limnetic zooplankton may be related to the absence of permanent physico-chemical boundaries and lack of predation pressure in the open water.     

Trophic ecology of the Lake Superior wave zone: a stable isotope approach

Stable carbon and nitrogen isotope ratio analyses were used to characterize the primary energy sources and trophic positions of 16 common Lake Superior wave zone invertebrate species. Isotope data from six tributary species that were taxonomically and ecologically matched with common wave zone species revealed broad energetic separation between these similarly structured benthic food webs. Previously published stable isotope data for Lake Superior wetland and pelagic food webs were used to assess the relative importance of inter-habitat energy flow within the Lake Superior ecosystem. The results of these comparisons indicate that the Lake Superior wave zone is energetically distinct from its tributaries, wetlands, and to a lesser extent from its vast pelagic realm. This information and approach should prove useful in future studies on the bioenergetics of inter-zonal migrants and other species that forage in multiple habitats within the lake and also in revealing energetic connections among terrestrial, riverine, littoral, and pelagic food webs in the coastal ecosystems of Lake Superior.     

城市新建湖泊浮游动物群落结构特征及其驱动因素——以南通紫琅湖为例

城市新建湖泊具有生态系统不稳定、受人类活动干扰强度大、水体流动性差等特点。浮游动物作为水域生态系统的重要组成部分,对湖泊生态系统的健康和稳定有重要作用,因此探究其群落结构形成机制对城市新建湖泊生态系统的合理构建和水质保护具有重要意义。本研究以城市新建湖泊——江苏南通紫琅湖为例,于2019年1月至2020年10月对浮游动物群落特征及其驱动因子进行了研究。共鉴定浮游动物61种（轮虫39种,枝角类11种,桡足类11种）,优势种12种（轮虫11种,桡足类1种）;三大类群的丰度和生物量差异显著,均为轮虫>桡足类>枝角类,其中轮虫的丰度为（1468.9±367.0）ind./L,占比达97.2%,生物量为（1762.6±442.0）μg/L,占比达88.2%,为浮游动物群落丰度和生物量最大的贡献类群,表明紫琅湖浮游动物群落整体呈现小型化特征。冬春季的优势种更替率最大（R=60.0%）,春夏季的优势种更替率最低（R=18.2%）。紫琅湖浮游动物多样性季节变化明显,且多样性阈值评估显示紫琅湖浮游动物多样性较低,整体处于“一般”水平。生物多样性指数对水质状况的评估结果显示,紫琅湖春季、夏季和秋季的水质状况处于α⁃中污型,冬季处于多污型。Spearman相关性分析和冗余分析表明浊度、叶绿素a、总磷是紫琅湖浮游动物群落特征形成的主要驱动因素。     

Compensation in individual growth rates and its influence on lake trout population dynamics in the Michigan waters of Lake Superior

The role of compensatory mechanisms in the population dynamics of lake trout in the Michigan waters of Lake Superior was explored during three time periods: the pre-sea lamprey period, prior to 1950 when lake trout were at a relatively high abundance and the fishery was the primary source of lake trout mortality; the sea lamprey dominant period, from 1951 to 1961 when lake trout were at a very low abundance due to sea lamprey predation and overexploitation; and currently, from 1985 to 1993 when wild lake trout abundance was at a moderate level. The role of compensatory changes in growth and fecundity rates of lake trout in the Michigan waters of Lake Superior was evaluated using a life table approach. Individual growth and fecundity rates were calculated and compared between time periods. These rates were used to determine age-specific fecundity which, along with age-specific survival, were incorporated into a Leslie projection matrix to calculate the finite rate of population increase (λ). Individual growth rates and age-specific fecundity rates changed in response to the different levels of lake trout abundance during each of the study periods. Lake trout during the sea lamprey dominant period, which experienced the lowest abundance and highest mortality levels, exhibited the fastest individual growth rates and the highest age-specific fecundity. These high rates contributed to the relatively large compensatory scope exhibited by lake trout during the sea lamprey dominant period as compared to lake trout during the pre-sea lamprey or the current periods which are associated with higher levels of abundance.     

Metabolic activity of herbivorous zooplankton in Lake Kinneret (Israel) during 1972-1977

Metabolic activities of herbivores zooplankton in Lake Kinneretduring 1972–1977 were analysed, based on experimentaldata. Two multiannual cycles of activity were observed: I-1972-1974;II-1975-1977. Some changes of nutritional value of the grazedmaterial in the 1975–1977 cycle are suggested.     

徐州市云龙湖大型底栖动物群落演变及环境影响因子分析

【目的】了解江苏省徐州市云龙湖大型底栖动物的群落结构及其环境影响因子,可以为保护云龙湖水生态环境提供依据。【方法】于2013—2017年对云龙湖大型底栖动物和水环境因子进行了调查。利用1/16 m2彼得逊采泥器采集大型底栖动物样品,同时利用有机玻璃采水器采集水样,每年的5月和10月各采样一次,共采样10次。利用3种群落多样性指数(Shannon-Wiener指数、Margalef物种丰富度指数、Pielou均匀度指数)评价云龙湖大型底栖动物的群落结构,选择ShannonWiener指数进行水质评价,并应用典型相关分析(CCA)得出大型底栖动物与环境因子之间的关系。【结果】云龙湖大型底栖动物群落结构简单,物种较少,3种群落多样性指数年际波动不大。云龙湖水质多年处于轻污染到中污染水平之间。优势物种中水丝蚓属的主要影响因子是总氮浓度,摇蚊幼虫的主要影响因子为高锰酸盐指数。【结论】云龙湖的水体有富营养化风险,应对云龙湖大型底栖动物的保护和水质改善给予足够重视。     

The Lake Superior varve stratigraphy and implications for eastern Lake Agassiz outflow from 10,700 to 8900 cal ybp (9.5-8.0 C ka)

Glaciolacustrine rhythmites within sediment cores from Lake Superior record the regional recession of the Laurentide Ice Sheet (LIS) from 10,700 to 8900 cal ybp [ca. 9.5-8.0 ¹⁴C ka]. LIS retreat from Superior opened eastern Lake Agassiz outlets so that the rhythmites reflect the combined impacts of sediment-laden meltwater and Lake Agassiz discharge. Multiple rhythmite stratigraphies, a time series analysis of the thickness measurements, and high-resolution inorganic carbonate data demonstrate that this is an annual record (varved). The varve thickness records primarily document regional ice margin dynamics; correlative thick varve sequences at 9100 cal ybp [∼ 8.1 ¹⁴C ka] and 10,400-10,200 cal ybp [∼ 9.2-9.0 ¹⁴C ka] record two periods of enhanced glaciofluvial discharge, most likely moraine formation (the Nakina and Nipigon). General varve cessation is associated with the circumvention of Lake Agassiz and glacial meltwater into Lake Ojibway at 9040 cal ybp [∼ 8.1 ¹⁴C ka], although adjacent to the inlets from Lake Nipigon, rhythmic sedimentation persisted for 200 years.Positively identifying Lake Agassiz catastrophic discharge events remains speculative but seems feasible. Following retreat of Marquette ice that had re-advanced to fill the basin, the initial influx of Lake Agassiz water is expected at around 10,600 cal ybp [∼ 9.4 ¹⁴C ka], but at this time, most of northeastern Lake Superior was covered by ice. Three sets of thick-thin varves in western Lake Superior perhaps record influxes of Lake Agassiz at around 10,630, 10,600, and 10,570 cal ybp [∼ 9.4 ¹⁴C ka]. Varve formation in Superior coincides with high lake levels in Lake Huron, suggesting that high lake levels in Huron correspond to periods of high Agassiz and/or meltwater flow into Lake Superior.     

Structural phase diagrams of animal communities in assessment of freshwater ecosystem conditions

A phase diagram method, using indices of biological diversity, was applied to describe the dynamics of zooplankton and fish community structure in natural and experimental conditions. The phase diagram is constructed in the coordinates H and dH × dt^–1, where H is the index of diversity of the community. The method reveals zones of steady state of a community and demonstrates community dynamics in undisturbed and disturbed conditions. Analysis of zooplankton dynamics in a fishless pond showed that in the absence of disturbances the community enters a zone of steady state (around dH × dt^–1=0) and stays in it for a long time. Under the action of disturbances (e.g. oxygen depletion for fish, influence of heavy metals for zooplankton) the community leaves the steady state zone. The greater the disturbance, the more the system deviates from steady state.