三门湾海域冬夏季口足目和十足目虾类的种类组成、时空分布及多样性分析

根据2007年12月和2008年6月三门湾海域的2个航次的渔业资源调查资料,研究三门湾海域口足目与十足目中虾类在冬季和夏季的密度、优势种及多样性的时空分布,并结合该调查海区的地形地貌和水文等因素对虾类的分布进行分析.结果表明,三门湾海域虾类以广温、广盐种为主,其夏季种类数高于冬季,且夏季虾类质量和尾数密度均值亦高于冬季...     

云南省澜沧拉祜族自治县浮游生物多样性研究

为了解澜沧拉祜族自治县浮游生物多样性及水质状况,于2017年3月、8月和11月,分为3个不同时期进行浮游生物采样.通过对澜沧县浮游生物定性和定量分析,根据密度、生物量、多样性指数和指示生物对澜沧县水质进行评价,弥补了澜沧县县内无相关研究的空缺.采集到澜沧县浮游植物共7门97属270种,以硅藻门和绿藻门为优势类群;浮游动...     

三门湾大型底栖动物群落结构及其与环境因子的关系

为了解三门湾大型底栖动物群落的现状和动态变化,分别于2015年11月、2016年2月、5月和8月在三门湾海域用阿氏拖网对大型底栖动物进行调查。结果表明: 经鉴定,大型底栖动物有119种,主要类群为鱼类、甲壳类和软体动物,占种类总数的79%。大型底栖动物全年优势种为细螯虾、长额超刺糠虾和六丝钝尾虾虎鱼,不同季节优势种的变化明显,种类差异性较大。大型底栖动物的年平均生物量和平均栖息密度分别为0.025 g·m^-2和0.07 ind·m^-2。三门湾大型底栖动物各季节的Shannon多样性指数为2.21～3.18,Margalef物种丰富度指数为3.25～3.78,Pielou均匀度指数为0.53～0.79。ABC曲线分析显示,在春季和冬季,群落受到中等程度干扰;而在夏季和秋季,群落受到轻微扰动。典范对应分析结果显示,水深、温度、盐度和pH值是影响大型底栖动物群落的最主要环境因子。     

三门湾浮游动物的季节变动及微型浮游动物摄食影响

2002年8月、11月、2003年2月和5月,在三门湾进行了4个航次生物、化学和水文等专业综合调查。根据采集的浮游动物样品的分析鉴定及海上现场实验结果,对浮游动物的群落组成、生物量、丰度、多样性指数的分布和季节变动及其浮游动物对浮游植物的摄食影响进行研究。结果表明,三门湾浮游动物有67属,89种,16类浮游幼体,主要可划分为4个生态类群：以近岸低盐类群为主,其优势种为中华哲水蚤Calanus sinicus、真刺唇角水蚤Labidocera etwhaeta、捷氏歪水蚤Tortanus derjugini、太平洋纺锤水蚤Acartiapacifica、中华假磷虾Pseudeuphausia sinica和百陶箭虫Sagitta bedoti等。半咸水河口类群、暖水性外海类群和广布种相对较少。浮游动物生物量和丰度的平面分布趋势除了夏季有所差异外,其它季节基本一致。2月份和5月份,浮游动物生物量和丰度,从湾顶向湾口呈逐渐增加趋势;8月份,湾口区生物量最高,而丰度高值区出现在湾顶部;11月份,生物量和丰度的平面分布相对均匀。浮游动物种类多样性指数有明显的季节变化,其动态变化与浮游动物种数和丰度的变化一致。微型浮游动物对浮游植物存在摄食压力,且有季节变化,摄食率的变化在0．18．0．68d^-1,微型浮游动物的摄食率低于相同季节的浮游植物生长率。微型浮游动物对浮游植物摄食压力的变化范围为16．1％-49．1％d^-1,对初级生产力摄食压力的变化在58．3％-83．6％d^-1。11月份,微型浮游动物对浮游植物和初级生产力的摄食压力均出现最高值。     

三门湾大型底栖动物时空分布及其与环境因子的关系

2006年11月、2007年1月、4月和8月在三门湾18个采样点对大型底栖动物进行调查,分析了其时空分布及其与环境因子的关系.结果表明:调查共采集到大型底栖动物124种,其中多毛类44种、软体动物34种、甲壳动物22种、棘皮动物11种、其他类动物13种;多毛类和软体动物种数占总种数的62.9％,二者构成了三门湾大型底栖动物的主要类群.双鳃内卷齿蚕、小头虫和不倒翁虫是春季三门湾大型底栖动物的优势种;不倒翁虫、双鳃内卷齿蚕和海稚虫为夏季的优势种;不倒翁虫、小头虫、双鳃内卷齿蚕和白沙箸为秋季的优势种;双鳃内卷齿蚕、不倒翁虫、小头虫和海稚虫为冬季的优势种.三门湾大型底栖动物年均生物量为17.36 g·m-2,年均栖息密度为72 ind·m-2.不同季节大型底栖动物的平均生物量和平均栖息密度存在显著性差异.大型底栖动物群落平均Shannon多样性指数在1.53 ～ 1.89,平均Margalef物种丰富度指数在2.25 ～2.96,平均均匀度指数在0.83 ～0.94,3个指数在不同季节间均存在显著性差异.经典范对应分析,影响三门湾大型底栖动物群落的主要环境因子包括海水的温度、盐度、溶解性无机氮以及表层沉积物中的有机质、总氮和总磷等,环境变量可以较好地解释主要类群的变化.     

青藏高原柴达木盆地尕海盐湖浮游生物群落多样性特征的初步研究

青海尕海是青藏高原柴达木盆地比较典型的高盐度且具有丰富卤虫资源的盐湖 ,海拔高程 2 849.6m。 1997年夏季我们对尕海盐湖浮游生物主要类群群落多样性特征进行了初步调查。调查期间在内湖主要水体 5个断面2 2个采样站共发现浮游藻类 46种 ,平均密度为 5 4.39× 10 4 Cells/L ;浮游动物 12种 ,全湖平均密度为 8.2 2个 /L ,平均生物量 0 .2 9mg/L。通过盐度含量较高 (119g/L)的内湖主要水体采样断面与盐度含量较低 (1.8g/L)的湖西北岸小水面采样断面比较 ,浮游生物不论是在种类组成特征、群落的多样性还是其个体丰度都存在十分明显的差异。结果表明 :在盐湖生态系统中 ,盐度是决定生物物种多样性及其个体丰度的关键因素之一。     

嘉陵江浮游生物群落结构研究

为揭示嘉陵江梯级水库浮游生物群落结构特征,按枯水期和丰水期对嘉陵江12个梯级水库24个样点进行浮游生物的野外采集,分析其群落结构的物种组成,并采用Shannon-wiener指数、Margalef指数和Pielou均匀度指数进行分析.结果表明:嘉陵江四川段浮游植物共8门42科95属171种,浮游动物的组成共有4纲9目21科30属62种;浮游动物优势种类有21种.浮游生物评价结果表明梯级库区水质处于中度污染状态.     

浙江三门湾浮游动物优势种空间生态位

生态位与种间竞争、资源利用密切联系,体现了物种在群落中利用资源的能力.为探明三门湾浮游动物分布格局的形成和影响因素,分别采用Shannon公式和Petrailis指数测定了浮游动物优势种生态位宽度和生态位重叠,并通过典范对应分析研究生态位分化状况.结果表明：百陶带箭虫、背针胸刺水蚤、短尾类幼虫等沿岸种的空间生态位较宽,而肥胖软箭虫、中华假磷虾等外海种的空间生态位较窄;具有捕食 被捕食关系的不同类群物种（如箭虫、仔鱼和水母分别与桡足类）有较高的生态位重叠,而同一类群物种（如桡足类及箭虫）间的生态位重叠值较低;浮游动物分布受温度、盐度和叶绿素a的影响较大,受营养盐影响较小.浮游动物空间生态位与生活类型、种间竞争、摄食等多种因素相关.
     

北冰洋微型浮游生物分布及其多样性

近年来随着全球气候变化对北冰洋生态环境的影响日益显现,北极微型浮游生物生态学研究得到了广泛的重视和实质性的进展。对北冰洋微型浮游生物的主要类群:异养细菌、古菌、光合异养原核生物和微型真核生物的分布及其多样性研究进展做了概述,并在此基础上展望了未来北冰洋微型浮游生物学研究。     

雅鲁藏布江湘河流域浮游生物群落结构的探究与多样性分析

为了探究雅鲁藏布江湘河流域生物群落结构及物种多样性现状,为西藏地区湘河流域浮游生物资源的保护及开发利用提供科学依据。本研究于2017年3～4月对湘河流域浮游生物进行了生物采样与调查,共设置采样点8个。本次调查共检出浮游植物6门61种,其中硅藻门为优势种,共41种,占总种类数的67.21%;绿藻门、蓝藻门次之,分别占总种类数的11.48%;甲藻门、隐藻门与金藻门种类较少。浮游植物密度范围为0.43×10~5～7.2×10~5cells/L,生物量范围为0.036～2.03 mg/L。共检出浮游动物3门44种,其中原生动物门为优势种,共30种,占总种类数的68.18%;轮虫13种;枝角类1种。浮游动物密度范围为1.5×10~5～1.66×10~6cells/L,生物量范围为0.9×10~(-3)～5.7×10~(-2)mg/L。各调查点浮游植物/浮游动物Shannon-Wiener多样性指数(H)和均匀度指数(E)平均分别为4.38/3.13和0.93/0.93。多项指数综合评价表明,湘河流域水质处于轻度污染或清洁状态,浮游生物群落结构单一,密度及生物量较低,生态环境较脆弱。     

密云水库的浮游生物群落

2002年4～10月对密云水库浮游生物群落的调查结果显示：浮游植物有6门,58属,122种,细胞密度为565．30～10^4cells／L,4月份硅藻(Bacillariophyta)占优势,6～10月蓝藻(Cyanophyta)占绝对优势．浮游植物优势种群有水华微囊藻(Microcystis flas-aquae)、颗粒直链藻(Melosira granulata)、梅尼小环藻(Cyclotella meneghiniana)、角甲藻(Ceratium hirundinella)等。浮游动物有36种,密度为4761ind/L;浮游动物具有原生动物在数量上占绝对优势．轮虫次之,枝角类与桡足类数量较少的特点。浮游动物的优势种群有弹跳虫(Halteria grandinella)、急游虫(Stromlridium uiHde)、针簇多肢轮虫(Polyarthra trigla)、螺形龟甲轮虫(Keratella cochlearis)、广布中剑水蚤(Mesocyclops leuckarti)、长额象鼻蚤(Bosmlna longirostris)等．与1980年监测结果相比,密云水库浮游生物总密度上升较快,群落结构和优势种群也发生了明显变化．浮游生物优势种群的指示作用显示,在植物生长季节,库区水体已进入富营养状态。     

Seasonal dynamics of zooplankton and grazing impact of microzooplankton on phytoplankton in Sanmen Bay, China

The species composition, biomass, abundance and species diversity of zooplankton were determined for samples collected from 12 stations in Sanmen Bay, China, in four cruises from August 2002 to May 2003. Growth of phytoplankton and grazing rates of microzooplankton were measured using the dilution technique. The spatial and temporal variation of zooplankton and its relationship with environmental factors were also analyzed. The results showed that a total of 89 species of zooplankton belonging to 67 genera and 16 groups of pelagic larvae were found in Sanmen Bay. The coastal low-saline species was the dominant ecotype in the study area, and the dominant species were Calanus sinicus, Labidocera euchaeta, Tortanus derjugini, Acartia pacifica, Pseudeuphausia sinica and Sagitta bedoti. Maximum biomass was recorded in August, followed by November and May, and the lowest biomass was recorded in February. Similarly, the highest abundance of zooplankton was observed in August, followed by May, November, and February. Grazing pressure of microzooplankton on phytoplankton in Sanmen Bay existed throughout the year, although the grazing rate of microzooplankton on phytoplankton varied with the season. Estimates for growth rate of phytoplankton ranged from 0.25 d^?1 to 0.89 d^?1, whereas grazing rate of microzooplankton ranged between 0.18 d^?1 and 0.68 d^?1 in different seasons. The growth rate of phytoplankton exceeded the grazing rate of microzooplankton in all the seasons. Grazing pressure of microzooplankton on phytoplankton ranged from 16.1% d^?1 to 49.1% d^?1, and the grazing pressure of microzooplankton on primary production of phytoplankton ranged from 58.3% d^?1 to 83.6% d^?1 in different seasons.     

Seasonal dynamics of zooplankton and grazing impact of microzooplankton on phytoplankton in Sanmen Bay, China

The species composition, biomass, abundance and species diversity of zooplankton were determined for samples collected from 12 stations in Sanmen Bay, China, in four cruises from August 2002 to May 2003. Growth of phytoplankton and grazing rates of microzooplankton were measured using the dilution technique. The spatial and temporal variation of zooplankton and its relationship with environmental factors were also analyzed. The results showed that a total of 89 species of zooplankton belonging to 67 genera and 16 groups of pelagic larvae were found in Sanmen Bay. The coastal low-saline species was the dominant ecotype in the study area, and the dominant species were Calanus sinicus, Labidocera euchaeta, Tortanus derjugini, Acartia pacifica, Pseudeuphausia sinica and Sagitta bedoti. Maximum biomass was recorded in August, followed by November and May, and the lowest biomass was recorded in February. Similarly, the highest abundance of zooplankton was observed in August, followed by May, November, and February. Grazing pressure of microzooplankton on phytoplankton in Sanmen Bay existed throughout the year, although the grazing rate of microzooplankton on phytoplankton varied with the season. Estimates for growth rate of phytoplankton ranged from 0.25 d⁻¹ to 0.89 d⁻¹, whereas grazing rate of microzooplankton ranged between 0.18 d⁻¹ and 0.68 d⁻¹ in different seasons. The growth rate of phytoplankton exceeded the grazing rate of microzooplankton in all the seasons. Grazing pressure of microzooplankton on phytoplankton ranged from 16.1% d⁻¹ to 49.1% d⁻¹, and the grazing pressure of microzooplankton on primary production of phytoplankton ranged from 58.3% d⁻¹ to 83.6% d⁻¹ in different seasons.     

基于Ecopath模型的三门湾生态系统结构与功能

生态系统的结构决定生态系统的物质循环、能量流动和系统功能.本研究采用Ecopath模型,根据2017-2018年中国东海三门湾海洋生态实地调查数据,构建了三门湾生态系统的生态通道模型,描述了三门湾生态系统的能流结构,分析了其功能特征.结果显示:三门湾生态系统营养级范围在1～3.80,能流渠道主要表现为牧食食物链,系统能...     

Attributes of the plankton flora at Bushehr,Iran

The plankton flora on the northeastern coast of the Gulf of Persia consists of many diatom species, the coccolithophores Gephyrocapsa oceanica and Coccolithus huxleyi, and the blue-green alga, Trichodesmium thiebautii. These are prevalent throughout the year and always at low concentrations, with an average maximum in January of 14463 cells/liter and minimum in June of 802/liter. Such comparative constancy suggests that the flora has the attribute of stability. The individual species fluctuate in a patternless, uncorrelated manner, so that the flora is characterized by the attribute of unpredictability. The turbidity of the shallow water reduces the light so that light is usually neither limiting nor inhibitory. There is a small amount of nitrate always available and ample phosphate and silicate. Pure culture studies of several species show growth from about 12° to 34°. The water was 34° in August of 1977. The flora's responsiveness to these light, nutrient, and temperature quantities makes possible its recovery to normal after advective disturbance in June 1977.Contribution number 4574 from the Woods Hole Oceanographic Institution.Contribution number 4574 from the Woods Hole Oceanographic Institution.     

Changes in the plankton community following introduction of filter-feeding planktivorous fish

1. We conducted enclosure experiments in a shallow eutrophic lake, in which a biomass gradient of the filter-feeding planktivore, silver carp, Hypophthalmichthys molitrix Valenciennes, was created, and subsequent community changes in both zooplankton and phytoplankton were examined.
2. During a summer experiment, a bloom of Anabaena flos-aquae developed (≈ 8000 cells mL⁻¹) solely in an enclosure without silver carp. Concurrent with, or slightly preceding the Anabaena bloom, the number of rotifer species and their abundance increased from seven to twelve species (1700–14 400 organisms L⁻¹) after the bloom in this fish-free enclosure. Protozoans and bacteria were generally insensitive to the gradient of silver carp biomass.
3. During an autumn experiment, on the other hand, large herbivorous crustaceans were more efficient than silver carp in suppressing the algae, partly because the lower water temperature (≈ 24 °C) inhibited active feeding of this warm-water fish and also formation of algal colonies. Heterotrophic nanoflagellate and bacterial densities were also influenced negatively by the crustaceans.
4. Correspondence analysis (CA) was applied to the weekly community data of zooplankton and phytoplankton. A major effect detected in the zooplankton community was the presence/absence of silver carp rather than the biomass of silver carp, whereas that in the phytoplankton community was the fish biomass before the Anabaena bloom, but shifted to the presence/absence of the fish after the bloom.     

Responses to fish predation and nutrients by plankton at different levels of taxonomic resolution

1. To improve mechanistic understanding of plankton responses to eutrophication, a mesocosm experiment was performed in the shallow littoral zone of a south Swedish lake, in which nutrient and fish gradients were crossed in a fully factorial design. 2. Food chain theory accurately predicted total biomass development of both phyto‐ and zooplankton. However, separating zooplankton and algae into finer taxonomic groups revealed a variety of responses to both nutrient and fish gradients. 3. That both nutrients and fish are important for phytoplankton dynamics was seen more clearly when viewing each algal group separately, than drawing conclusions only from broad system variables such as chlorophyll a concentration or total phytoplankton biovolume. 4. In some taxa, physiological constraints (e.g. sensitivity to high pH and low concentrations of free CO₂) and differences in competitive ability may be more important for the biomass development than fish predation, grazing by herbivorous zooplankton, and nutrient availability. 5. We conclude that food chain theory accurately predicted responses in system variables, such as total zooplankton or algal biomass, which are shaped by the dynamics of certain strong interactors (‘keystone species’), such as large cladocerans, cyanobacteria and edible algae (<50 μm), whereas responses at finer taxonomic levels cannot be predicted from current theory.