东海浮游翼足类(Pteropoda)环境适应类型的划分

根据1997-2000年东海23°30'-33°N、118°30'-128°E海域4个季节海洋调查资料,采用浮游翼足类物种丰度和同步温、盐度数据,构造相关数学模型,计算其最适温度和最适盐度.同时参考生态特征分析,划分东海浮游翼足类物种生态类型.结果表明,东海浮游翼足类鉴定到种的共有20种.在翼足类优势种中,尖笔帽螺(Creseis acicula)和马蹄螔螺(Limacina trochiformis)是具有广温广盐特征的亚热带外海种;拟海若螺(Paraclione longicaudata)、球电螺(Cavolinia globulosa)和胖螔螺(Limacina inflata)是热带大洋种;强卷螺(Agadina syimpsoni)、厚唇螺(Diacria trispinosa)、龟螺(Cavolinia tridentata)和角长吻龟螺(C.longirostris var.angulata)是适温较低的亚热带外海种;其余都是典型的亚热带外海种.东海浮游翼足类总体上显示出典型的暖水性生态类型.拟海若螺和胖螔螺具有较小的盐度分布区间,是台湾暖流或黑潮暖流向北扩展的指示种.现代东海浮游翼足类优势种的地理分布,与古代东海底质沉积物分析结论相一致.浮游翼足类种类生态类型的划分在古海洋气象、海洋地质、海洋物理和海洋生物等学科研究中具有重要的意义.     

东海海樽类数量分布及与环境的关系

提要根据1997—2000年东海23°30′—33°00′N、118°30′—128°00′E海域4个季节海洋调查资料,采用方差贡献和逐步回归分析方法探讨东海海樽类的数量变化和相应的动力学。结果表明,海樽类是东海浮游动物第二大类群,在数量上仅次于桡足类,其丰度春季最高,夏季次之,冬季最低;冬、春和夏季的东方双尾纽鳃樽(Thalia orientalis)和冬、秋季的小齿海樽(Doliolum denticulatum)是影响海樽类数量分布的主要优势种;海樽类高丰度区常位于暖流与各水团交汇处的偏暖流一侧,其数量变化的动力主要来自暖流势力的消长。海樽类在东海出现率较低,集群性强,较高丰度的分布仅局限在暖流势力范围内,其高丰度水域是东海暖流锋面的一个重要标志。     

东海浮游介形类(Ostracods)分布特征

根据1997~2000年东海(23°30'~33°00'N,118°30'~128°00'E)海域四季海洋调查资料,探讨了东海浮游介形类分布特征及与环境的关系.结果表明:东海浮游介形类丰度占浮游动物总丰度的3.47%;春、夏、秋和冬四季平均丰度分别为0.70,1.72,2.57和0.90个/m3;冬春季的短棒真浮萤(Euconchoecia chierchiae),夏季的后圆真浮萤(Euconchoecia maimai)和秋季的齿形海萤(Cypridi-na dentata)分别是各季的主要优势种;夏、秋季介形类总丰度与水文环境因子的线性相关性不显著,春季与表层盐度相关,冬季与表层温度相关.东海北部外海四季均有介形类高丰度区出现,但在东海北部近海长江口及其邻近舟山水域,介形类数量相对较低.在东海南部,冬春季高丰度区位于外海,夏秋季在近海.东海浮游介形类基本上是一大类较为典型的暖水性且具有集群行为的海洋浮游动物.介形类秋季高丰度区和较高丰度区的分布与太平洋褶柔鱼(Todarodes pacificus)、绿鳍马面鲀(Navodon Septentrionalis)、鲐鯵鱼类等渔场的位置基本一致,在渔业上有重要的意义.     

东海浮游动物生物量分布特征

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.     

东海东南部浮游动物生物量的分布特征

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。     

2000年夏季南极普里兹湾及邻近海域浮游植物研究

报道了2000年夏季(1月)在62°~69°S,70°30'~75°30'E的南极普里兹湾邻近海域浮游植物种类组成、丰度分布、叶绿素a浓度及其环境调控.结果表明,调查海区共有浮游植物4门33属65种、变种和变型.浮游植物平均细胞丰度为32.67×103个/dm3.浮游植物细胞丰度和叶绿素a浓度高值均出现在水体较稳定的近岸海湾和冰间湖及毗邻陆架,在大陆坡和深海区它们的值明显减小.浮游植物细胞丰度和叶绿素a浓度在0~50m水层最大,100m以下水层随深度的增加而减小.浮游植物丰度呈昼夜变化,在13:00丰度最高.浮游植物优势种为短菱形藻(Nitzschiacurta),占总丰度的24.8%.浮游植物种类组成和细胞丰度与浮冰和水团稳定性有关.经回归分析,浮游植物细胞丰度与水温、溶解氧成显著正相关,与无机磷(PO_{43--P)和无机氮(NO3--N)成显著负相关.}     

台湾海峡东部海域海樽类被囊动物的分布

本文根据对1997至1999年3个航次在台湾海峡东部海域(23°30'～25°30′N,118°30′～121°00′E)采集的大型浮游动物样品的分析,首次专文报道了该海域浮游海樽类(Thaliacea)被囊动物的种类组成和数量分布,其中夏季的种类最多(11种),数量最大,平均丰度达7445×10-3个 m3,优势种是东方双尾纽鳃樽(Thaliademocraticaorientalis)、软拟海樽(Doliolettagegenbauri)和韦氏纽鳃樽(Weeliacy lindrica),而冬季的种类和个体数量最少,仅小齿海樽(Doliolumdenticulatum)的出现率较高.文章讨论了海樽类分布与水温、盐度及浮游植物丰度的关系,并与邻近海域海樽类的分布状况作了比较.     

北黄海典型水域秋冬季浮游植物群落的昼夜变化

利用冬季(2007年1月)和秋季(2007年10月)在北黄海中部昼夜连续观测所获浮游植物样品,分析了浮游植物群落的昼夜变化.结果表明:浮游植物丰度在各层存在昼夜变化,冬季10～20 m层主要在白天出现高丰度,而20～30 m层和30～底层都是在夜间出现高丰度,冬季丰度垂直分布相对较均匀.秋季各层都主要在夜间出现高丰度,丰度垂直分布是下层水体明显比上层高.2个季节优势种昼夜组成都比较稳定.冬季优势种为具槽帕拉藻(Paralia sulcata),主要分布在下层水体.秋季罗氏角毛藻(Chaetoceros lauderi)和密连角毛藻(Chaetoceros densus)成为优势种,两者分别以下层和上层水体分布较多.冬季浮游植物群落多样性和均匀度昼夜变化都不明显,秋季0～10 m层和20～30 m层多样性和均匀度昼夜变化较明显.从季节变化来看,秋季多样性要高于冬季,均匀度的季节变化不明显.     

东海西北部中层冷水特征的时空变化

根据1959～1996年3～6月水温资料,按30'×30'方区统计计算了东海西北部中层冷水的8个示性特征值,并绘制了平面分布图.分析结果表明,东海西北部中层冷水于3月出现,4月形成,5月达到盛期,6月消衰,其生消规律具有明显的季节性;其出现的海区为28°～31°N,124°E以西(即台湾暖流路径)海域,具有明显的地域性.示性特征的时-空分布变化反映出:在形成期,地域性表现充分;在消衰期,反映出中层冷水下方的台湾暖流对它的影响明显;而在盛期,示性特征则为上述的过渡型.这为探讨海洋热、动力因子对其生消机制的影响奠定了实验基础.     

南麂列岛国家海洋自然保护区微,小型藻类生态研究：Ⅱ.数量分布

本文对南麂列岛国家海洋自然保护区不同生境中的微、小型藻类的丰度和季节变化及其与环境因子之间的关系进行了研究。海水中浮游藻类的年平均丰度为１２０×１０４个／ｍ３;沉积物中底栖藻类年平均丰度为２１６×１０４个／ｃｍ２;潮间带中微、小型藻类年平均丰度为１９６６０３个／ｇ或１７７９３个／ｃｍ２。海水中微、小型藻类丰度的季节变化为夏季高于秋季高于春季高于冬季;潮间带以个／ｃｍ２表示的藻类丰度的季节变化为春季高于夏季高于秋季高于冬季,这与大型海藻丰度的变化趋势基本相似;以个／ｇ表示的藻类丰度的季节变化为春季高于秋季高于冬季高于夏季,这与大型底栖动物总生物量的变化趋势完全一致。南麂海域微、小型藻类丰度与盐度、溶解氧浓度呈正相关,与营养盐（Ｎ、Ｐ、Ｓｉ）含量之间呈负相关。     

Study on abundance variation of pteropods in the East China Sea

1 Introduction Pteropoda, an order of marine pelagic mollusks, belongstoClassGastropoda,SubclassOpisthobranchia. The speciesofthisorder can be found all over the world buttheyareusuallyabundantinthecontinentalshelfand continental slope area. As fish diets…     

Distribution pattern of pelagic amphipods and its affecting facors in the East China Sea

1 IntroductionAmphipoda, an order of marine pelagic shell-fish, belongs to class Crustacea, subclass Malacost-raca (Chen and Shi,2002). Species of this ordercan be found all over the world, especially in tropi-cal and subtropical oceans. As fish diets, th…     

崇明东滩潮沟浮游动物数量分布与变动

根据2008年4-12月对上海市崇明岛东滩潮沟进行4个季节的浮游动物调查资料,研究了崇明东滩潮沟浮游动物的数量分布及变动。结果表明,调查区浮游动物总丰度较高,四季变化明显。受潮汐作用的影响,夏、秋、冬三季落潮时丰度大于涨潮时,春季涨潮时丰度则大于落潮时。浮游动物在6条潮沟的平面分布不均匀,春季东旺沙边滩区和北八边滩区的数量明显多于近团结沙边滩区,夏、秋季分别以东旺沙边滩区和北八滧边滩区的数量最多,冬季则以近团结沙边滩区的数量最多。主要优势种细巧华哲水蚤(Sinocalanus tenellus)、中华华哲水蚤(Sinocalanus sinensis)、火腿许水蚤(Schmackeria poplesia)、四刺窄腹剑水蚤(Limnoithona etraspina)和四刺破足猛水蚤(Mesochra quadrispinosa)等数量的季节、潮汐变化及各时期的空间分布格局差异明显,其数量分布情况决定了浮游动物总数量的分布。盐度是影响冬、春季涨潮时浮游动物总丰度分布的主要因子,水温则是影响夏、秋季涨潮时总丰度分布的主要因子。此外,径流及潮流等动力因素对潮沟浮游动物数量的时空分布也产生重要影响。     

Seasonal distribution of Calanus sinicus (Copepoda, Crustacea) in the East China Sea

On the basis of the four-season investigation in 23°30′~33°N and 118°30′~128°E of the East China Sea from 1997 to 2000, the seasonal distribution of Calanus sinicus was studied with aggregation intensity, regression contribution and other statistical methods. It was inferred that C. sinicus’s predominance presented from winter to summer, especially in spring and summer, because its dominance amounted to 0.62 and 0.29 respectively. The percent of its abundance in copepod abundance was 76.71% in summer, greater than 66.60% in spring, greater than 19.02% in winter, greater than 4.02% in autumn. The occurrence frequency in winter and spring was 83.08% and 93.89%, higher than that in summer and autumn, 76.71% and 73.87%. Compared with other dominant species of copepods, C. sinicus’s contribution to the copepod abundance was obviously greater than that of the other species in winter, summer and spring, but smaller in autumn. C. sinicus tended to have an aggregated distribution. The clumping index peaked in summer (50.19), followed in spring (19.60), declined in autumn (13.18) and was the lowest in winter (3.04). The abundance changed in different seasons and areas, relating to temperature but not salinity in spring and autumn, to salinity but not temperature in summer; to neither temperature nor salinity in winter. In spring and summer, its high abundance area was often located in the mixed water mass formed by the Taiwan Warm Current, the Huanghai Sea Cold Water Mass, the coastal water masses and the Changjiang Dilute Water. In spring and autumn, its abundance was affected by the warm current, as well as the runoff from continental rivers affected it in summer. It can be inferred that C. sinicus was adapted to wide salinity and temperature, as a euryhalinous and eurythermous species in the East China Sea.     

Species composition,diversity and density of plagic Ostracoda in the East China Sea

On the basis of seasonal investigations at 23°30'~33°00'N,118°30'~128°00'E of the East China Sea during 1997~2000,dynamics on the density and diversity of Ostracoda was discussed.Results showed that totally 26 species were identified.The Ostracoda diversity was opposite to the change of its density in most seasons which reflected an uneven assignment of Ostracoda density among its different species.The Ostracoda density was 0.70 ind./m3 in spring,1.72 ind./m3 in summer,2.57 ind./m3 in autumn and 0.90 ind./m3 in winter.Euconchoecia chierchiae in spring and winter,Euconchoecia maimai in summer and Cypridina dentata in autumn were main dominant species in each season.The Ostracoda density did not show an obvious linear relationship with the hydrologic factors in summer and autumn,but was related to the surface salinity in spring and the surface temperature in winter.Its high density areas mainly distributed in the north offshore in all the seasons while in the south offshore in winter and in spring,and the south nearshore in summer and autumn,implied the zooplankton was a typical warm water animal,whose high density distribution in autumn were located in a similar position to Todarodes pacificus,Navodon Septentrionalis,Scomber japonicus and other fishes in the sea,so as to be an important indicator for fishing ground.The main species dominating in Ostracoda now are different from the species twenty years ago probably attributes to global warming.     

渤海西南部小型水母群落特征与环境因子相关性研究

根据2020年8月至2021年5月对渤海西南部浮游动物调查的4个航次数据,分析该海域水螅水母、栉水母群落结构和季节变化特征,讨论了环境因子对小型水母丰度的影响。研究发现,渤海西南部小型水母种类组成和丰度分布存在季节变化,全年调查共发现小型水母13种,11种水螅水母、2种栉水母;春、夏、秋、冬该海域水母种数分别为4种、9种、7种和2种,丰度均值分别为30.74 ind./m3、30.78 ind./m3、12.08 ind./m3、0.57 ind./m3;优势种为嵊山秀氏水母（Sugiura chengshanense）、八斑芮氏水母（Rathkea octopunctata）、锡兰和平水母（Eirene ceylonensis）、半球美螅水母（Clytia hemisphaerica）、球型侧腕水母（Pleurobrachia globosa）,优势种季节更替率平均为91.67%,呈现明显季节演替。水温和盐度是影响渤海西南部小型水母丰度季节变化的主要环境因子,春季水温回升及适宜营养盐含量促进小型水母生长繁殖,夏季桡足类为小型水母提供了丰富的饵料促进其生长,秋季群落主要受盐度的影响。根...     

黄海中部太平洋磷虾的大小组成和丰度分布的季节变化及其与环境因子的关系

The seasonal size structure and spatial abundance distributions of Euphausia pacifica populations were investigated in the central part of southern Yellow Sea from August 2009 to May 2010.The abundance and biomass of E.pacifica were higher in spring and summer,and lower in autumn and winter.The mean abundance and biomass(calculated by carbon)were 74.94 ind./m~3 and 8.23 mg/m~3,respectively.Females with total length(TL)ranging between 10 and 19 mm in summer had a substantial contribution to the population biomass,whereas larvae of TL of 3–7 mm in spring were the main contributor to the population abundance.The sex ratio(female:male)showed a female bias in four seasons.Its value peaked in summer,and then decreased in autumn,spring,and winter successively.Cohort analysis revealed that the length-frequency distribution of E.pacifica could be characterized as one group with large animals(mean TL12 mm)accompanied by one or two subgroups of small individuals(mean TL7 mm).Regarding the spatial distribution,juveniles and adults of E.pacifica tend to concentrate in relatively deep water with low temperature(～11℃)and high salinity(32),whereas its larvae showed more abundance in inshore water with rich chlorophyll a,low salinity(32),and warm temperature(11℃),especially in summer and autumn.Associations changed seasonally between stage-specific abundance and environmental factors.