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1.
为验证运用浮游动物图像扫描分析系统(Zoo Scan Integrated System,Zoo Scan)研究浮游动物群落结构的可行性,作者利用Zoo Scan图像技术,对2013年8月在南黄海(30°—37°N,125°E以西)14个站位采集到的中型浮游生物网(孔径160μm)样品进行了处理,分析了浮游动物混合样品的体积生物量与实测干重、含碳量和含氮量的相关关系,在此基础上研究了南黄海夏季浮游动物群落结构,并与历史资料进行了比较。结果表明,浮游动物混合样品的总体积生物量与总实测干重、含碳量和含氮量具有极显著的相关关系,但在500—1000μm和2000μm粒径组相关关系不显著,这与粒径组的类群组成有关。南黄海夏季浮游动物可划分为四个组群:黄海中部组群、黄海近岸组群、黄东海交汇区组群1和2。其中,黄海中部组群和黄海近岸组群与历史研究中的稳定群落相一致。不同组群的地理分布受使用的浮游生物网型和季节变化的影响。研究表明,Zoo Scan图像技术为我国近海浮游动物群落结构的研究提供了一种快速、可行的方法。 相似文献
2.
秋季黄海WP2型网采浮游动物的群落特征 总被引:1,自引:0,他引:1
《中国海洋大学学报(自然科学版)》2015,(7)
中国传统的海洋浮游动物调查方法存在对中小型浮游动物数量低估的情况。为了较全面地掌握黄海浮游动物群落特征、弥补黄海浮游动物研究的有关不足,作者采用国际通用的WP2型浮游生物网,于2012年11月对黄海海域(121°00′E~124°30′E,32°00′N~39°44′N)的中型浮游动物的种类组成、丰度和优势种进行调查,并结合环境因子对浮游动物的群落结构进行分析。本航次共鉴定浮游动物成体119种,浮游幼虫25类。该海区浮游动物平均丰度(不含夜光虫)为4 331.0ind/m3。优势种以小拟哲水蚤和拟长腹剑水蚤小型桡足类为主。根据各站位间浮游动物组成的相似程度和地理分布,将黄海区域的浮游动物分为北黄海群落、黄海中部群落、苏北沿岸群落和东海近岸混合水群落。与以往大型浮游生物网采资料相比,本次调查的浮游动物丰度要高出一个数量级,体型较小的浮游动物的优势地位显著提升,但群落划分结果没有明显差别。 相似文献
3.
东海东南部浮游动物生物量的分布特征 总被引:5,自引:0,他引:5
本文基于1986~1990年间对东海黑潮及其邻近海域所进行的6个航次的调查资料,对该海域浮游动物生物量的平面分布、垂直分布、季节变化特征及其与环境因子的关系进行了探讨。结果表明,生物量秋季最高,冬季最低,春、夏季介于两者之间;平面分布的总趋势是陆架区高于黑潮区,测区北部高于南部;高生物量区通常出现在不同海流、水团的交汇锋面和黑潮次表层水的涌升区,主要由暖水广布种和热带大洋广布种组成;生物量垂直分布与水深的关系可以用表示,高生物量出现于100m以浅水层;饵料浮游动物生物量与仔鱼丰度有显着的正相关关系。此外,东海中部的浮游动物高生物量区(29°N、126°E附近)与东海中部鲐渔场的位置颇为一致。 相似文献
4.
2011年春夏季黄海和东海微型浮游动物类群组成及其摄食的研究 总被引:1,自引:0,他引:1
为了解春夏季黄海和东海微型浮游动物类群及其摄食生态,于2011年春季和夏季在黄海、东海,通过稀释法测定浮游植物生长率及微型浮游动物对浮游植物的摄食率,同时应用显微分析技术研究了微型浮游动物丰度及其类群组成.结果表明:(1)春季,黄海、东海微型浮游动物丰度为1800~21833个/dm3,夏季的为67~6175个/dm3;春季,其微型浮游动物生物量为8.71-60.58ug/dm3,夏季的则为0.44~30.25ug/dm3(其生物量以c含量计).(2)春季、夏季黄海和东海浮游植物的生长率及其标准偏差分别为0.78±0.35、1.62±0.83d-1,而春季的显著低于夏季(P〈0.05).春季、夏季其微型浮游动物的摄食率及其标准偏差分别为0.98±0.32、0.92±0.57d-1,无显著性差异(p〉0.05).春季,微型浮游动物摄食浮游植物现有生物量的61%±13%,占初级生产量的131%±58%;夏季,微型浮游动物摄食浮游植物现有生物量的54%±22%,占初级生产量的70%±44%.春、夏季,黄海和东海微型浮游动物对浮游植物初级生产量的摄食比例较高. 相似文献
5.
本文分析研究中日黑潮合作调查(1986~1992年连续7年)在东海北部黑潮及其邻近海域采集的浮游生物样品,并就饵科浮游动物的生物量分布及其与海洋环境的关系,作概要总结.结果表明,调查区浮游动物生物量较低,年平均仅71.22mg/m3.生物量的季节变化不明显,盐度是影响调查区浮游动物生物量季节变化和年际变动的重要因素.东海黑潮锋和对马暖流锋在200m等深线附近海域,从北到南把调查区划分为东西两部分:在西部海域,生物量大于50mg/m3;在东部海域,生物量小于50mg/m3.不同生态类群浮游动物及其生物量的时空分布,基本上反映了调查区各个季节水文状况的基本特点. 相似文献
6.
东海浮游动物生物量分布特征 总被引:24,自引:1,他引:23
根据1997~2000年东海海域23°30'~33°00'N,118°30'~128°00'E分别进行4个季节的海洋调查资料,对东海区浮游动物总生物量及饵料生物量的数量变动,时空分布及与鱼渔场关系作了分析.结果表明,四季总生物量均值为65.32mg/m3,其中秋季大于夏季大于春季大于冬季;饵料浮游动物生物量均值为40.9mg/m3,约占总生物量的60%,其中秋季大于夏季大于冬季大于春季.总生物量与饵料生物量平面分布趋势基本一致,高生物量(250~500mg/m3)区分布范围极小,一般占总调查面积的1%~4%.东海北部近海125°00'E以西,29°30'N以北水域生物量季节变化最明显.饵料浮游动物生物量平面分布取决于甲壳动物丰度的分布.饵料浮游动物生物量与鳀鱼中心渔场及其仔、稚鱼高密集区分布存在着较好的对应关系,春季鳀鱼中心渔场(>100kg/h1)和仔、稚鱼高密集区(≥100尾/网)位于东海中南部(28°00'~29°30'N)饵料浮游动物最高生物量(100~250mg/m3)密集区内或边缘水域. 相似文献
7.
基于水色遥感的黄、东海叶绿素a浓度季节和年际变化特征分析 总被引:2,自引:1,他引:1
海洋叶绿素a浓度是衡量海洋浮游植物的生物量和富营养化程度的最基本指标之一。黄、东海叶绿素a浓度年际变化显著,其影响因素需深入分析。本文依据黄、东海的地理位置、水深和生态特征将其分为5个区域进行研究。由5个区域叶绿素a浓度的季节变化可以看出,水华发生早晚依次是黄海西岸—北黄海中部—南黄海中部—东海陆架区—东海近岸海区。从年际变化可以看出,除东海陆架外,其它4个区域的变化幅度均较大。在冬季和夏季,5个区域的基础生物量在2008年均达到最低;在春季和秋季,黄、东海近岸和北黄海中部的年际变化较大,5个区域在2006年春季均达到最高;2009年秋季较其它年份均低。5个区域基础生物量由高到低为:黄、东海近岸较高,然后是北黄海中部和南黄海中部,东海陆架最低。从与水温、风速和有效光合辐射的相关分析来看,浮游植物生长的年际变化受海面风速的影响较大。近岸区域水体混合均匀,营养盐丰富,风速较小时水体稳定有利于浮游植物生长,而水深较深区域,风速较大时,营养盐易补充到表层,有利于浮游植物生长。 相似文献
8.
于2019年12月使用4种不同型号网具采集了珠江口浮游动物, 进行形态学鉴定和DNA分子鉴定, 分析珠江口浮游动物的群落结构特征, 并比较不同调查方法对浮游动物丰度和生物量结果的影响。形态学镜检鉴定浮游动物36种(类), 其中浮游幼虫6类。浅水I型浮游生物网采集的浮游动物平均丰度为115±96ind.·m-3, 平均生物量为0.21±0.14g·m-3; 浅水Ⅱ型浮游生物网采集的浮游动物平均丰度为3536±2444ind.·m-3, 平均生物量为0.56±0.33g·m-3; 浅水Ⅲ型浮游生物网采集的浮游动物平均丰度为4314±4172ind.·m-3, 平均生物量为0.50±0.25g·m-3; 25#浮游生物网采集的浮游动物平均丰度为6741±3826ind.·m-3, 平均生物量为4.33±3.42g·m-3。研究结果表明网具孔径大小对浮游动物研究结果具有重要影响, 三个站点水体DNA样品注释出15种浮游动物; 使用浅水Ⅱ型网采集的DNA样品注释出19种浮游动物; 镜检样品鉴定浮游动物17种。水体DNA样品能检测出更多的微型浮游动物如原生动物等; 网采样品能过滤更多的水样, 有利于采集更多的大中型浮游动物, 更能充分反映优势类群如桡足类的种类和数量。研究结果表明, 水体DNA可检出浮游幼虫和原生动物等较难镜检鉴别的种类, 采用不同型号网具采集浮游动物可以更全面地反映研究海域浮游动物的群落结构特征。多种调查方法的结合有助于全面了解研究海域的生态环境状况。 相似文献
9.
春、秋季东、黄海营养盐的分布变化特征及营养结构 总被引:19,自引:1,他引:18
利用2000年10~11月和2001年3~4月的调查资料,分析讨论了春、秋季东、黄海营养盐的分布变化特征及营养结构状况。结果表明:该海域表层营养盐高值主要出现在长江冲淡水影响区和江浙近海海域,低值出现于东海陆架区和黄海西北部,黄海中部水域春、秋季因温跃层强弱不同表层营养盐含量差别较大。东、黄海海域春、秋季表层水N/P、Si/N和Si/P值(除秋季黄海北部局部水域N/P值小于10外)均远高于Redfield比值。春季东海海域N/P、Si/N和Si/P值明显高于黄海海域,并高于秋季;秋季黄海海域N/P、Si/N和Si/P值要高于东海海域,变化也大于春季。在强温跃层存在期间和浮游生物旺发季节,表层水域N/P、Si/N和Si/P值原本高的区域往往进一步升高,而温跃层较弱或浮游植物生长繁殖能力较弱的季节,表层水域N/P、Si/N和Si/P值将略有降低。东、黄海水域浮游植物光合作用受N限制的可能性极小,绝大部分水域主要是受P限制,Si的含量普遍较高,它不可能成为限制因子。长江冲淡水区和江浙近海海域过量的N及高N/P值特性且持续升高的趋势可能是近20年来这一地区富营养化程度加剧、赤潮频发的主要原因。 相似文献
10.
为了解黄、渤海浮游动物群落特征, 利用2014年春季在黄、渤海采集的浮游动物样品, 对浮游动物的种类组成、丰度、生物量、优势种和生物多样性进行分析, 分析浮游动物群落结构与环境因子间的相关关系, 并划分了浮游动物群落。共记录浮游动物78个种类(南黄海69种、北黄海42种、渤海47种), 浮游幼虫占比最高。研究海域的浮游动物平均丰度为3 183.8±7 829.7 ind./m3, 剔除夜光虫(Noctiluca scintillans)后, 平均丰度为537.3±554.2 ind./m3; 平均生物量为409.1±517.5 mg/m3。夜光虫、中华哲水蚤(Calanus sinicus)和强壮箭虫(Sagitta crassa)是黄、渤海的共同优势种。结合香农-威纳指数和累积优势度曲线分析, 渤海浮游动物的生物多样性最低, 北黄海次之, 南黄海的多样性最高。聚类分析表明, 研究海域浮游动物群落可划分为渤-黄海沿岸群落、黄海中部群落和南黄海-东海近岸混合水群落。相关性分析显示, 研究海域与浮游动物群落结构相关性最高的环境因子组合为温度、盐度和叶绿素a浓度。 相似文献
11.
As one of the important microzooplankton in marine pelagic habitats, tintinnids are classified as neritic genera,oceanic genera and cosmopolitan genera. Until now, we know little about the interaction between neritic and oceanic genera in continental shelves. Low species richness area was found in the mixing area between neritic and oceanic genera in the East China Sea. In this study, we investigated the spatial distribution of tintinnid community throughout the entire Bohai Sea in May(spring) of 2014 to find out:(1) whether the tintinnid assembalges differed in the three major bays bordering this shallow inland sea;(2) whether there was low species richness area in the Bohai Sea. Three genera and 11 species attributed to neritic and cosmopolitan taxa were reported from this region. Tintinnid abundance averaged(81±216) ind./L(0–1 234 ind./L). Tintinnid community differed within the three major bays, with each characterized by different tintinnid taxa. Referring to the average abundance of three bays, tintinnids were most abundant in the Laizhou Bay((328±445) ind./L), and least abundant in the Liaodong Bay((34±57) ind./L). A low species richness area occurred in the central Bohai Sea(20–40 m isobaths), in some stations of which no tintinnid was recorded. Our study demonstrates that tintinnid community varied greatly over small spatial scales, and low species richness area was found in the mixing area between neritic and oceanic genera within this inland sea. 相似文献
12.
春、秋季南黄海浮游纤毛虫丰度及生物量的分布差异 总被引:1,自引:0,他引:1
Seasonal variation of marine plankton spatial distribution is important in understanding the biological processes in the ocean.In this study,we studied spatial distribution of planktonic ciliate abundance and biomass in the central deep area(station depth greater than 60 m) and the coastal shallow area(station depth less than 60 m) of the southern Yellow Sea(32°–36.5°N,121°–125°E) in spring(April) and autumn(October–November) of 2006.Our results showed that both ciliate abundance and biomass in the surface waters were higher in spring((1 490±2 336)ind./L;(4.11±7.81) μg/L) than in autumn((972±823) ind./L;(1.11±1.18) μg/L,calculated by carbon).Ciliate abundance and biomass in the surface waters of the coastal shallow area were similar in spring and autumn.However,in the central deep area,those values were much higher in spring((1 878±2 893) ind./L;(5.99±10.10)μg/L) than in autumn((738±373) ind./L;(0.74±0.76) μg/L).High values of ciliate abundance and biomass occurred in the central deep area in spring and in the coastal shallow area in autumn.Mixotrophic ciliate Laboea strobila was abundant in the central deep area in spring,when a phytoplankton bloom occurred.However,in autumn,L.strobila was abundant in the coastal shallow area.Boreal tintinnid Ptychocyli obtusa was found in spring.Both L.strobila and P.obtusa were concentrated in the surface waters when their abundance was more than 1 000 ind./L.Peaks of these species were in the subsurface waters when their abundance was less than 400 ind./L.This study showed that both high abundance and biomass of ciliates occurred in different areas in southern Yellow Sea seasonally. 相似文献
13.
14.
Seasonal variability of the zooplankton community in the southwest of the Huanghai Sea (Yellow Sea) Cold Water Mass 总被引:2,自引:0,他引:2
Samples were collected with a plankton net in the four seasonal cruises during 2006-2007 to study the seasonal variability of the zooplankton community in the southwest part of Huanghai Sea Cold Water Mass (HSCWM, Yellow Sea Cold Water Mass). The spatial and temporal variations of zooplankton species composition, biomass, abundance and biodiversity were examined. A total of 122 zooplankton species and 30 pelagic larvae were identified in the four cruises. Calanus sinicus and Aidanosagitta crassa were the most dominant species, and Themisto gaudichaudi and Euphausia pacifica were widely distributed in the HSCWM area. The spatial patterns of non-gelatinous zooplankton (removing the high water content groups) were similar to those of the total zooplankton biomass in autumn, but different significantly in the other three seasons. The seasonal means of zooplankton biomass in spring and summer were much higher than that in autumn and winter. The total zooplankton abundance averaged 283.5 ind./m~3 in spring (highest), 192.5 ind./m~3 in summer, 165.5 ind./m~3 in autumn and 65.9 ind./m~3 in winter (lowest), and the non-gelatinous groups contributed the most total abundance. Correlation analysis suggests that the non-gelatinous zooplankton biomass and abundance had a significant positive correlation in the whole year, but the relationship was insignificant between the total zooplankton biomass and abundance in spring and summer. The diversity index H of zooplankton community averaged 1.88 in this study, which was somewhat higher than historical results. Relatively low diversity in summer was related to the high dominance of Calanus sinicus, probably due to the strongest effect of the HSCWM in this season. 相似文献
15.
台湾海峡西部海域软质海底多毛类的生态 总被引:2,自引:0,他引:2
本文根据1984-1985年4航次底栖生物调查资料,首次全面地研究了台湾海峡西部海域多毛类的种类组成,数量分布及其与环境因子的关系。结果表明,该海域多毛类404种,习见种191种,区系属亚热带性质;平均生物量4.33g/m^2,平均栖息密度68个/m^2;有沿岸性和外洋性两种明显不同的生态类型,前者位于沿岸水系常年控制海域,种类多,数量较大,后者位于南部粗粒沉积物分布区,种类较少;多毛类高数量区与 相似文献
16.
The South Huanghai Sea and the East China Sea lie on the east continental shelf ofChina. These areas are generally under the effects of river, coastal currents, and coldwater in the Huanghai Sea, as well as the branches of Kuroshio. Therefore, obviously, thephysical oceanography, chemical elements and plankton distribution in these areas areconsiderably complicated. As for plankton composition, there are temperate neriticspecise, brackish water and estuarine species, coastal species and also tropical pelagicspecies. Each community of the plankton occupies a distributional area of its own.Among the communities there exists a transitional area caused by horizontal andvertical mixing of water masses which effect this area in different degrees. All commu-nities and the transitional area are more or less relatively stable, except for seasonal varia-tion. 相似文献
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Alessandra Pugnetti Anna Maria Bazzoni Alfred Beran Fabrizio Bernardi Aubry Elisa Camatti Mauro Celussi Joan Coppola Erica Crevatin Paola Del Negro Alessandro Paoli 《Marine Ecology》2008,29(3):367-374
The changes in the plankton biomass structure in relation to nutrient inputs were studied in the Gulf of Venice (Northern Adriatic Sea), an area characterized by a very marked trophic state variability. The investigation was carried out at two stations, in March, May and July 2005 and 2006, considering the whole water column. The size structure (from picoplankton to mesozooplankton) of both autotrophs and heterotrophs was analysed. Signals of diluted waters and nutrient inputs were more marked in 2005 than in 2006. In 2005, the total plankton biomass was almost double (87 ± 37 μg·C·l?1) that in 2006 (44 ± 26 μg·C·l?1). The variations were determined mainly by phytoplankton, with a 70% decrease, and a shift from a community dominated by microphytoplankton (49 ± 12%) in 2005 to one dominated by bacteria (43 ± 11%) in 2006 was observed. The relationship between the heterotrophic (H) and autotrophic (A) biomass indicated a rapid decline of the H/A ratio with increasing phytoplankton biomass. This study, although temporally limited, is consistent with the results reported for other marine environments and it seems to confirm the importance of nutrient inputs in structuring the biomass of plankton community. 相似文献
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DistributionofbiomassofzooplanktonintheKuroshioareaoftheEastChinaSea¥MengFan;ChenShiqunandWuBaoling(FirstinstituteOfOceanogra... 相似文献
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Elaine S. Fileman Tania Fitzgeorge-Balfour Glen A. TarranRoger P. Harris 《Estuarine, Coastal and Shelf Science》2011
The plankton community composition comprising heterotrophic bacteria, pro-/eukaryotes, heterotrophic nanoflagellates, microzooplankton and mesozooplankton was assessed during the spring bloom and at non-bloom stations in the English Channel and Celtic Sea between 6 and 12 April 2002. Non-bloom sites were characterised by a dominance of pro-/eukaryotic phytoplankton <20 μm, higher abundance of heterotrophic nanoflagellates, microzooplankton standing stocks ranging between 60 and 380 mg C m−2, lower mesozooplankton diversity and copepod abundance of between 760 and 2600 ind m−3. Within the bloom, the phytoplankton community was typically dominated by larger cells with low abundance of pro-/eukaryotes. Heterotrophic nanoflagellate cell bio-volume decreased leading to a reduction in biomass whereas microzooplankton biomass increased (360–1500 mg C m−2) due to an increase in cell bio-volume and copepod abundance ranged between 1400 and 3800 ind m−3. Mesozooplankton diversity increased with an increase in productivity. Relationships between the plankton community and environmental data were examined using multivariate statistics and these highlighted significant differences in the abiotic variables, the pro-/eukaryotic phytoplankton communities, heterotrophic nanoflagellate, microzooplankton and total zooplankton communities between the bloom and non-bloom sites. The variables which best described variation in the microzooplankton community were temperature and silicate. The spatial variation in zooplankton diversity was best explained by temperature. This study provides an insight into the changes that occur between trophic levels within the plankton in response to the spring bloom in this area. 相似文献