高位虾池养殖过程浮游植物群落的演替

通过对湛江东海岛北寮村和庵里村各2个高位虾池养殖过程的浮游植物演替和主要理化因子进行调查,研究浮游植物群落的演替过程对高位虾池的健康养殖的影响.结果表明:4池共检出浮游植物7门76属140种;对虾生长正常的北寮高位虾池演替优势种主要有螺旋环沟藻、椭圆扁胞藻、海链藻、湖泊束球藻密胞变种、裸甲藻、卵囊藻、微囊藻、锥形斯克里普藻、色球藻和尖尾蓝隐藻等,而对虾发病的庵里高位虾池演替优势种主要有铜绿微囊藻、柔弱布纹藻、咖啡形双眉藻、小席藻、卷曲鱼腥藻、水生集胞藻、衣藻、尖尾蓝隐藻和螺旋环沟藻等,北寮正常虾池浮游植物种类(包括优势种)较对虾发病的庵里虾池多而复杂;对虾生长正常池优势种的演替快而门类交替,而对虾发病池呈现硅藻到蓝藻优势的演替;对虾生长正常池浮游植物密度随养殖过程延伸呈上升态势,而对虾发病池浮游植物密度初期增加病害后下降;养殖过程浮游植物密度与主要理化因子的相关关系不显著;对虾生长正常的北寮高位池多样性指数与均匀度高于对虾发病的庵里高位池,而优势度却较低.水体理化因子变化平缓,浮游植物有较高的多样性指数和均匀度、较低的优势度对于稳定虾池养殖水环境有重要作用.     

大庆库里泡浮游植物群落结构及多样性研究

2012年5月—10月, 大庆库里泡浮游植物的种类组成、丰度、优势种及多样性调查研究结果表明, 库里泡共鉴定浮游植物380个分类单位(349种29变种2变型), 隶属于8门11纲22目41科104属。库里泡浮游植物群落组成主要是绿藻—硅藻型, 浮游植物种类数随季节的变化顺序为: 8月>6月>7月>5月>9月>10月。浮游植物丰度季节性变化明显, 变化范围为5.94×105—119×105 ind•L–1。浮游植物优势种不同季节间既有交叉又有演替, 优势种类大多为中营养型和中—富营养型指示种。多样性评价结果表明, 浮游动物被长期高强度捕捞后, 库里泡的浮游植物群落种类组成比较丰富, 群落结构复杂且稳定性较好, 水体处于β—中污染至轻污染水平。     

淀山湖浮游植物群落特征及其演替规律

为探明淀山湖浮游植物群落结构演变与富营养化之间的关系,于2004-2006年对上海市最大天然淡水湖泊淀山湖的浮游植物进行逐月采样调查,分析其群落结构特征.共采集到淀山湖浮游植物84属205种,主要由绿藻(种类数占50%)、硅藻(20%)、蓝藻(13%)、裸藻(13%)等组成.相邻两月之间种类相似性系数呈现冬春季高、夏秋季低的趋势:优势种为银灰平裂藻(Merismopedia glauca)、小席藻(Phormidium tenus)、铜绿微囊藻(Microcystis aeruginosa)、具缘微囊藻(M.marginata)、湖泊鞘丝藻(Lyngbya limnetica)、微小色球藻(Chroococcus minutus),颗粒直链藻最窄变种(Melosira granulata var.angustissima )、啮蚀隐藻(Cryptomonas erosa)、小球藻(Chlorella vulgate)和四尾栅藻(Scenedesmus quadricauda)等.浮游植物群落细胞数量主要由蓝藻(42.73%)、绿藻(37.75%)、硅藻(12.67%)和隐藻(6.06%)组成;生物量主要由硅藻(36.75%)、蓝藻(16.78%)、绿藻(16.36%)和隐藻03.53%)等组成.淀山湖浮游植物群落结构季节演替模式不同于PEG(Plankton Ecology Group)模型,其中蓝藻从春末开始大量出现,夏季大量繁殖,一直延续到秋初.综合文献资料看出,淀山湖浮游植物群落已从1959年的硅藻一金藻型、1987-1988年的隐藻-硅藻型演变为2004-2006年的蓝藻-绿藻型;数量由1959年的103 ind./L上升至2004-2006年的1.11×107 cells/L.演替的总体趋势表现为:贫中营养型的金藻、甲藻比例下降,富营养型的蓝藻、隐藻和微型绿藻增加.浮游植物数量和群落结构的演变指示了淀山湖水体的富营养化进程.     

惠州沙田水库浮游植物群落特征及演替研究

2009 年7 月(丰水期)和12 月(枯水期)分别对沙田水库4 个样点进行浮游植物采集。检测出浮游植物58 种(含变种), 隶属7 门8 纲18 目31 科46 属。丰、枯水期均出现的优势种分别为史氏棒胶藻(Rhabdogloea smithii)、铜绿微囊藻(Microcystis aeruginosa)、微小多甲藻(Peridinium pusillum)、小球藻(Chlorella vulgaris); 仅在丰水期形成的优势种分别为简单棕鞭藻(Ochromonas simplex)、梅尼小环藻(Cyclotella meneghiniana)、针形纤维藻(Ankistrodesmus aciculars)和柯氏并联藻(Quadrigula chodatii); 而枯水期形成的优势种分别为分歧锥囊藻(Dinobryon divergens)、水溪绿球藻(Chlorococcum infusionum)。丰、枯水期丰度分别为(8.36±1.37)×10⁵ cell·L^-1 和(3.60±1.81)×10⁵ cell·L^-1; 生物量分别为1.34±0.55 mm³·L^-1 和0.43±0.43 mm³·L^-1; Shannon-Weaver 多样性指数变化范围在1.25-2.75 之间, 丰、枯水期水质分别为中营养和富营养水平。与2000 年结果比较, 浮游植物群落的物种组成由绿藻型更替为绿硅藻型, 丰度组成由蓝-绿藻型更替为绿-蓝-甲藻型; 清洁水体的优势种消失/减少, 耐污种类优势种增加, 其中绿藻优势种存在向小型、单细胞种类更替的趋势。     

东小磨虾池及其沿岸浮游植物群落物种多样性

１９９１年６～９月东小磨虾池及其沿岸浮游植物群落中出现过的浮游植物门类有硅藻、甲藻、蓝藻、绿藻、金藻和裸藻等,种类在９４种以上,以硅藻为主,达５９种。其中国内以前未记录过的海洋种类４种。虾池与沿岸的浮游植物群落物种多样性之间存在着一些差异。ＳｈａｎｎｏｎＷｅａｎｅｒ多样性指数的范围在０．１２～３．１７     

海珠国家湿地公园浮游植物群落结构时空变化

浮游植物是湿地生态系统的重要组成成分,其数量及群落结构变化会对湿地生态系统的结构和功能产生重要影响。为了解海珠国家湿地公园浮游植物群落结构及时空动态变化特征,于2017年冬、2018年夏两季分别进行了调查。结果表明:海珠国家湿地公园共检到浮游植物171种,隶属7门64属,其中绿藻门、硅藻门和蓝藻门种类分别占总种类的44%、26%和13%;广州平裂藻(Merismopedia cantonensis)和细小平裂藻(Merismopedia minima)在两季均为优势种,冬季啮蚀隐藻(Cryptomonas erosa)也较多;浮游植物群落结构、丰度与生物多样性指数具有明显季节变化,冬季硅藻和绿藻占优,分别占藻类总丰度的32%和29%;夏季蓝藻占绝对优势,占68%;夏季浮游植物平均丰度达(25.58±18.47)×10⁶cells·L^-1,约为冬季的3倍; Shannon物种多样性指数和Pielou均匀度指数冬季分别为4.38和0.77,夏季分别为2.92和0.51;从空间上看,海珠湖浮游植物种类、多样性指数均较低,而丰度较高;塘涌和西江涌硅藻...     

淮北采煤塌陷区小型湖泊浮游植物群落结构和季节动态

深入了解煤矿塌陷湖泊生态系统的结构与功能,有助于开展淮北煤矿塌陷水域的生态保护和资源的可持续利用。该文从2005年3月至2007年2月,研究了淮北采煤塌陷区两个小型湖泊(南湖和乾隆湖)浮游植物的群落结构和季节动态。结果表明:乾隆湖中总氮和总磷的浓度均高于南湖。蓝藻和绿藻均为南湖和乾隆湖的优势类群,其总和分别约占两湖泊年平均总浮游植物生物量的69.8%和63.3%,且南湖浮游植物生物量明显低于乾隆湖。另外,南湖夏季出现了以铜绿微囊藻(Microcystis aeruginosa)为主的蓝藻水华,而富营养湖泊中常见的微囊藻属(Microcystis)和水华束丝藻(Aphanizomenon flos-aquae)等蓝藻种类在乾隆湖中没有被观察到。除营养盐、温度外,鱼类和硬度水质可能是影响淮北采煤塌陷区小型湖泊浮游植物群落演替和生物量季节变化的重要原因。     

深澳湾浮游植物群落特征及其多样性研究

2007年1月～2008年12月对汕头深澳湾进行的浮游植物周年调查表明,深澳湾共有浮游植物64属178种。其中硅藻为最大的优势类群,共57属154种,占总种数的86.03%;甲藻5属23种;其它浮游植物类群2属2种。2007年和2008年浮游植物总丰度年均值分别为5.47×10⁷ cells·m^-3和2.26×10⁸ cells·m^-3。周年变动模式为单峰型(2007年和2008年的高峰分别位于7月和8月)。2007年和2008年多样性指数与均匀度指数范围分别是0.435～2.490、0.118～0.825和0.211～2.632、0.059～0.820,且夏季的多样性指数和均匀度指数都是最低的。中肋骨条藻Skeletonema costatum是该湾的全年优势种,其2007年和2008年优势指数与优势度年均值分别是55.17%、0.489与68.65%、0.652。中肋骨条藻的绝对占优已在很大程度上改变了该湾浮游植物的群落结构,并使中肋骨条藻赤潮的发生机率大大增加。深澳湾浮游植物的分布与水文、营养盐、滤食生物的摄食等均有一定的关系。     

三峡水库坝前水域浮游植物群落时空动态研究

于20122013 年对三峡水库坝前水域浮游植物组成、优势种、密度、生物量及多样性进行了周年季度调查, 共鉴定浮游植物151 种属, 其中绿藻门71 种, 硅藻门47 种, 蓝藻门20 种, 隐藻门和甲藻门各4 种,裸藻门和金藻门各2 种, 黄藻门1 种。浮游植物优势种的季节更替明显, 夏季和秋季优势种类为硅藻和绿藻,冬季为硅藻、蓝藻和绿藻, 春季为绿藻、硅藻和隐藻。浮游植物年均密度和生物量分别为3.95106 ind./L 和4.078 mg/L, 空间差异表现为支流和库湾远高于干流, 季节动态表现为夏季最高, 春季和冬季次之, 秋季最低。三峡水库坝前水域浮游植物多样性指数偏低, 水体污染类型属于-中污染。研究为客观了解三峡水库坝前水域浮游植物群落的空间分布与季节变化特征提供一定的参考依据。       

长诏水库浮游植物群落结构及水质评价

于2010年5月、8月和11月对新昌长诏水库浮游植物群落进行了调查,运用Shannon多样性指数(H)、Simpson多样性指数(D)、Margalef丰富度指数(M)及Pielou均匀度指数(J)分析了浮游植物种群的多样性,并结合水质理化指标对长诏水库的富营养化程度及水质状况进行了综合评价.结果显示:长诏水库浮游植物有6门26属(种),其中,绿藻门10属(种),硅藻门9属(种),蓝藻门4属(种),隐藻门1属,甲藻门1属,黄藻门1属.浮游植物的丰度为5.73×105～7.73×105ind·L-1,平均为(6.71±0.81)×105 ind·L-1;生物量为0.73～1.03 mg·L-1,平均为(0.83±0.12) mg·L-1.在水平分布上,蓝藻门、硅藻门和绿藻门的丰度在各采样点中均较高;在季节分布上,硅藻门、绿藻门、蓝藻门分别在春季、夏季、秋季占绝对优势.总体上,浮游植物丰度和生物量在水库入水口较高,出水口较低.水库浮游植物的多样性较差,水质受到较重污染,且主要为氮、磷污染;富营养化程度为中-富营养化水平.     

Seasonal succession of phytoplankton and its diversity in two highly eutrophic lakes with different conditions of stratification

Seasonal succession of phytoplankton biomass, its diversity and its photosynthetic activity in two highly eutrophic lakes have been compared. In order to test the intermediate disturbance hypothesis, the lakes have been chosen with almost the same level of trophy but different conditions of stratification, through two ice-free periods of open water with different weather conditions.High phytoplankton diversity throughout the period of investigation was characteristic for the shallower Lake Lobardzu. The number of species here was usually more than 30 and the Shannon diversity changed from 1.2 to 4.2. Owing to the frequent external disturbances, periods characterized by autogenic succession with establishing dominance and declining diversity alternated with periods of biomass reduction and rises of diversity and photosynthetic activity. In the warmer summer of 1983, with more intense warming of bottom layers and predominance of blue-greens, phytoplankton biomass was higher and diversity lower than in the cold summer of 1982.In stratified Lake Rudusku, phytoplankton diversity and number of species were usually much lower. During the long summer stratification up to three-four dominant species of blue-greens and dinoflagellates become established and competitive exclusion leading to low diversity advanced. Some changes in biomass and diversity, were caused by zooplankton activity.     

稻鱼共作生态系统浮游植物群落结构和生物多样性

稻鱼共作技术是中国传统农业的精华,通过对稻鱼共作系统水体浮游植物的种类组成、密度、生物量及多样性进行分析,明确该系统中浮游植物数量变化特性,为进一步开发利用这一经典农艺提供理论基础和实践依据。结果表明,稻田生态系统中浮游植物群落包含蓝藻门、甲藻门、隐藻门、裸藻门、绿藻门和硅藻门等6门,共38属93种。稻鱼共作显著增加稻田水体浮游植物的密度和生物量,降低硅藻和蓝藻的优势度,增加绿藻和裸藻的优势度,提高了稻田水体浮游植物多样性指数。     

Effects of mixing and silica enrichment on phytoplankton seasonal succession

During the summer of 1983, cryptophytes, diatoms, cyanophytes, and the dinoflagellate, Ceratium hirundinella were most prominant among the phytoplankton of Eau Galle Reservoir. In the open water, cryptophytes and diatoms peaked in the spring, cyanophytes were most successful in the early summer, and Ceratium was dominant from mid-July until early August. In general, the sequence of events corresponded quite closely to the model of seasonal succession developed by the Plankton Ecology Group of the International Society of Limnology. To a large extent, the same pattern held in four experimental water columns. Departures from the model involved the roles of specific nutrients in diatom and cyanophyte periodicity. Diatoms began to yield to cyanophytes in late spring despite intermittent mixing and silica enrichment. Although capable of buoyancy regulation and thus well adapted to stable water columns, cyanophytes had greater increases in biomass in mixed columns, and in those columns, were most successful during a period of intermittent mixing. Cyanophyte success varied inversely with TN : TP ratios during the period of intermittent mixing, but not subsequently. By mid-July, Ceratium dominated the phytoplankton of every column except that of a mixed column in which conditions favored cyanophytes and large diatom species.     

Diversity and succession of the phytoplankton in a small lake over a two-year period

Phytoplankton in the small central Finnish lake, Vasikkalampi, was studied over a two-year period by weekly sampling simultaneously with monitoring of physical and chemical properties of water, solar radiation energy and zooplankton. In the present paper, the fluctuations in phytoplankton diversity were studied in relation to environmental factors. The special aim for the study was to detect a relation between environmental disturbances and phytoplankton diversity.     

Ecology of the phytoplankton of the River Moselle: effects of disturbances on community structure and diversity

A data set on community composition of the phytoplankton of the River Moselle (France) has been used for testing the intermediate disturbance hypothesis (IDH). After a short presentation of the ecology of the river and of its phytoplankton, the main changes in composition and diversity of the suspended algal assemblage are described. It is emphasized that discharge fluctuations, related to weather changes, play a key role, but that biotic factors such as grazing and parasitism may also influence diversity in stable summer conditions.     

浙江天童山区灌丛群落的物种多样性及其与演替的关系

根据浙江天童山区灌丛群落的样地调查数据,采用Shannon－Wiener多样性指数、Simpson指数和群落均匀度指数研究了灌丛群落的物种多样性,并与当地的常绿阔叶林进行了比较。结果表明：这3种指标能够有效地表征亚热带灌丛群落的组成结构特征。天童灌丛群落灌木层的物种多样性指数 SW 高于常绿阔叶林中乔木层,而低于常绿阔叶林中灌木层。灌丛群落灌木层的生态优势度 SN 低于常绿阔叶林中乔木层,但高于常绿阔叶林中灌木层。灌丛群落灌木层的群落均匀度 PW 比常绿阔叶林中乔木层的和灌水层的都低。此外,文中还就本区灌丛群落物种多样性的特点,讨论了加速其进展演替的恢复措施。     

Importance of intermediate disturbances for the species composition and diversity of phytoplankton in two very different Berlin lakes

Species composition and diversity of phytoplankton were studied for several years in two lakes which differ with respect to mixing conditions and nutrient limitation: Schlachtensee regularly stratifies very stably. In contrast, size and wind-exposure predispose Lake Tegel to deeper mixing; additionally, stratification is artificially destabilized by aeration. As the duration of aeration was varied, the study period includes interannual changes in mixing conditions. For both lakes, it also covers trophic change due to restoration; this was especially pronounced in Schlachtensee.Results show that mixing conditions affect species composition on two levels: on a superordinate level, lake morphology or hydrology govern stability of stratification and susceptibility to perturbation, and hence the extent to which motile species can develop. In Schlachtensee, species with some means of actively seeking preferred depths usually dominated during summer stratification: Planktothrix agardhii during the hypertrophic phase, and flagellates since restoration. In contrast, in Lake Tegel deeper mixing as a generally prevailing condition favored non-motile species. Their seasonal pattern was remarkably constant from year to year. Although changes in the extent of mixing were pronounced during the four years studied (1987–1990), these were within a range that affected species composition only slightly: in summer, cyanobacteria and diatoms represented climax species whose dominance was not offset by additional, weather-induced increases of turbulence.On a subordinate level, and within the constraints set by nutrient limitation as well as by grazing pressure, small-scale changes in mixing conditions caused by meteorological cycles were shown to strongly affect species composition and in consequence diversity: Results for the fouryear post-restoration study period at Schlachtensee show that considerable interannual variations of species composition and diversity can be attributed to variations in the frequency of meteorological changes. In accordance with the intermediate disturbance hypothesis (IDH), diversity was lowest during 1989, the year with the longest and most pronounced cycles of fair weather (14 to 27 fair days on end). However, the mechanism for this was rarely a decline of diversity caused by competitive exclusion within single long phases of stable conditions, as conceived by the intermediate disturbance hypothesis. Instead, diversity responded to changes in mixing conditions with a variety of patterns — often with low values during phases of increased mixing and with high values under quiescent conditions, especially during the first calm days just after increased mixing. Thus, not disturbance as such, but rather the rate of change between phases of disturbance and quiescence appears to determine the frequency of high diversity indices.In Lake Tegel, high diversity indices were somewhat more frequent in 1989, the year during which thermal stratification was most stable. For species adapted to frequent or continuous mixing, interjected calm phases with unusually high stability of thermal stratification may represent a disturbance of accustomed conditions. Thus, in turbulent Lake Tegel, meteorological cycles appear to act in reversal to the IDH, in a sense which may be termed intermediate quiescence hypothesis.Phosphorus limitation due to successful restoration was found to decrease winter and vernal diversity in Schlachtensee. Presumably, without nutrient constraints, new populations could grow more rapidly in response to the rapid changes of physical parameters during this season. In contrast, restoration has increased summer diversity, as phosphorus concentrations no longer allow the virtual monocultures of Planktothrix agardhii which prevailed previously. In Lake Tegel, the reduction of phosphorus concentration down to 60 µg/l P in 1989 limited biomass, but this level was still too high to significantly alter species composition or diversity.     

有机磷培养下水体浮游植物竞争与群落结构演替

磷是浮游植物生长的必要元素,也是调控水体富营养化的重要因子之一。在无机磷缺乏的水域,能够有效利用有机磷的藻类有可能成为浮游植物群落的优势种。为了研究有机磷对浮游植物群落结构演替的影响,分别从3个水库采集表层水样,西陂水库(硅藻70.3%,甲藻19.1%,绿藻9.3%)、山美水库(硅藻31.3%,甲藻59.2%,绿藻3.5%)、三十六脚湖(硅藻43.1%,甲藻50.5%,绿藻5.0%),选用有机磷单磷酸腺苷(Adenosine monophosphate,AMP)作为磷源进行实验室模拟实验,并与无机磷(NaH_2PO_4·2H_2O)作为磷源实验组做同步对比,探讨有机磷源条件下浮游植物竞争及群落结构演替规律。结果显示:AMP培养20 d后,西陂水库、山美水库和三十六脚湖的浮游植物生物量分别增加了6.5倍,2.1倍和1.9倍,浮游植物群落结构都演替为以甲藻门和绿藻门为优势藻,所占比例分别为81.8%和16.7%、55.2%和33.5%、73.2%和24.3%,其中西陂水库甲藻门拟多甲藻对有机磷AMP的利用能力强,其所占比例达到81.8%。表明有机磷AMP能有效地促进甲藻门拟多甲藻属的增殖,进而改变水体浮游植物群落结构。