桑沟湾浮游纤毛虫丰度和生物量分布的季节变化

于2011年4、8、10月及2012年1月对桑沟湾进行了浮游纤毛虫丰度和生物量的季节调查。纤毛虫的平均丰度为(7 552±10 979)个/L,范围为408~61 667个/L;纤毛虫的平均生物量(以碳计)为(4.79±5.77)μg/L,范围为0.35~33.09 μg/L。无壳纤毛虫丰度和生物量主要分布在湾内,湾中和湾外丰度相对较低;砂壳纤毛虫丰度和生物量在盐度较高的海区总体较高,呈现朝向外海分布的趋势。纤毛虫丰度和生物量的高值区春季主要出现在湾的西北,夏季向湾中部迁移,秋季主要出现在湾的西南,冬季主要出现在湾的西部,高值区随季节大致呈顺时针迁移的趋势。纤毛虫的丰度春季最高,冬季最低;生物量夏季最高,冬季最低。无壳纤毛虫夏季粒级较大,冬季粒级较小;砂壳纤毛虫壳的平均口径夏季较大,秋季较小。共鉴定出砂壳纤毛虫8属27种,其中拟铃虫属(Tintinnopsis)种数最多。砂壳纤毛虫在纤毛虫总丰度中的比例平均为16.3%±21.9%,夏季最高(36.3%±27.8%),冬季最低(4.9%±5.9%)。纤毛虫丰度与温度、盐度、Chl a浓度及微微型真核浮游生物丰度均没有明显的相关性,但与蓝细菌及异养细菌丰度呈显著的正相关关系。     

桑沟湾不同形态锰的分布、季节变化及影响因素

利用催化动力学分光光度法和两步提取法对2011年4月（春）、8月（夏）、10月（秋）和2012年1月（冬）桑沟湾海域溶解态无机锰(DIMn)和表层沉积物中的锰的含量进行测定。结果表明,桑沟湾4个季节（春季至冬季,后同）DIMn浓度呈现出近岸高、远岸低的分布特点,其平均浓度分别为(60.5±43.1) nmol/L、(42.0±30.5) nmol/L、(23.4±11.2) nmol/L和(18.2±13.5) nmol/L,呈现出明显的季节变化,即春季最高,夏季、秋季次之,冬季最低;与相邻的俚岛湾和爱莲湾相比,桑沟湾春季、夏季DIMn的浓度较高,秋季、冬季则没有显著性差异。桑沟湾表层沉积物中总Mn在4个季节的含量分别为(861±308) mg/kg、(915±322) mg/kg、(589±108) mg/kg、(653±185) mg/kg,表层沉积物中醋酸提取态Mn在4个季节的含量分别为(500±272) mg/kg、(502±232) mg/kg、(322±81) mg/kg、(345±91) mg/kg,两者均表现出近岸高、远岸低的分布特点。醋酸提取态Mn的含量在春季、夏季要显著高于秋季、冬季。悬浮颗粒物的吸附和浮游生物的利用是影响桑沟湾DIMn浓度与分布的重要因素。桑沟湾DIMn的源主要包括河流及地下水输送、大气输送、沉积物−水界面释放;汇主要包括养殖生物的清除、向黄海的输送等。简单箱式模型收支计算结果显示,桑沟湾DIMn的源略大于汇,表明除了养殖生物的清除和向黄海的输送,桑沟湾DIMn还存在其他汇。本研究的结果为桑沟湾DIMn的生物地球化学循环的深入认识提供了基础数据。     

三门湾微型浮游生物丰度的时空变化特征

粒径小于20 μm的微型浮游生物能迅速响应海洋环境变化,因而在海洋环境监测中起着重要作用。本文应用流式细胞技术研究了三门湾表层与底层海水中微型浮游生物（包括细菌、聚球藻、微型真核生物以及病毒）丰度的时空分布特征,探讨了微型浮游生物丰度与水体理化因子之间的关系。结果表明,三门湾海域微型浮游生物丰度范围:细菌,6.98×105~9.84×106 cells/mL;聚球藻,1.10×103~3.71×104 cells/mL;微型真核生物,1.04×103~3.75×104 cells/mL;病毒,1.01×106~3.47×107 mL-1。夏、秋两季表层微型浮游生物丰度均高于底层;秋季细菌、聚球藻和病毒丰度低于夏季,但微型真核生物丰度高于夏季;温度是造成微型浮游生物丰度季节差异的主要因素。微型浮游生物丰度的水平分布在夏季无显著规律,但秋季表底层均由内湾向外湾递减。秋季,除底层的细菌外,微型浮游生物丰度水平分布与pH和盐度呈显著负相关,同时与亚硝氮、硝氮、铵氮、叶绿素a呈显著正相关。     

乐清湾海域浮游动物群落分布的季节变化特征及其环境影响因子

2006年10月、2007年1月、4月及7月对乐清湾海域浮游动物群落的种类组成、优势种、生态类群、水平分布的季节性变化特征进行了调查,分析了浮游动物群落分布与环境因子的关系。结果表明,在调查海域共鉴定出浮游动物82种(包括浮游幼体11种),隶属于15大类,其中秋季为46种、夏季为42种、春季为25种和冬季为16种。乐清湾浮游动物可分为近岸低盐类群、暖水性近海类群、暖温带近海类群和暖水性广布类群4个生态类群,其中近岸低盐类群在全年均占优势,其它类群则呈现明显的季节变化。中华哲水蚤Calanus sinicus、真刺唇角水蚤Labidocera euchaeta、针刺拟哲水蚤Paracalanus aculeatus和背针胸刺水蚤Centropages dorsispinatus为调查海域主要优势种。浮游动物生物量年平均值为82.7mg/m3,其大小依序为:夏季(121.1mg/m3)>秋季(119.2mg/m3)>春季(48.5mg/m3)>冬季(42.2mg/m3);丰度年平均值为82.1个/m3,其大小依序为:夏季(193.4个/m3)>秋季(73.7个/m3)>春季(53.4个/m3)>冬季(9.8个/m3)。相同季节浮游动物生物量和丰度的平面分布趋势类似,季节间则存在明显差异。相关性分析结果表明,浮游动物物种数与水温、盐度、叶绿素a质量浓度和浮游植物细胞密度均呈极显著相关;丰度与水温、叶绿素a质量浓度和浮游植物细胞密度呈极显著相关;生物量与水温、叶绿素a质量浓度呈极显著相关。与历史资料相比,近30a来浮游动物数量呈下降趋势,但群落结构和组成没有发生明显改变。     

青岛太平湾砂质潮间带小型底栖生物丰度和生物量的研究

于2004年10月~2005年10月对青岛太平湾砂质潮间带进行了小型底栖生物的逐月采样,对丰度和生物量进行定量研究。结果表明,小型底栖生物的年平均丰度为(1 025.40±268.84)ind.10cm-2,平均生物量为(1 195.87±476.53)μgdwt.10cm-2,平均生产量为(10 762.80±4 288.77)μg dwt.10cm-2a-1。小型底栖生物在丰度和生物量上呈现了明显的季节变化,高值主要出现在4,5,6月,而低值在8,9月。共鉴定出l2个类群,线虫在丰度上占绝对优势(89.2%)。按生物量,多毛类占46.9%,其次为线虫31%。其它较多的类群还有涡虫、桡足类、腹毛虫、寡毛类等。50%以上的小型底栖生物分布在0~4cm表层,冬季部分向下迁移。Pearson相关分析表明,小型底栖生物数量对间隙水溶氧表现出明显的滞后效应,而与盐度、pH和沉积物环境因子相关性不明显。     

桑沟湾浮游植物多样性年际变化

研究了桑沟湾20 a中4个年度网采浮游植物多样性的年际变化,研究结果表明,2003-2004年度浮游植物物种数量较1983-1984年度明显减少;浮游植物α-多样性指数周年变化规律近乎"双峰"型,2003-2004年度α-多样性指数较1989-1990、1999-2000两年度均有明显降低(P<0.01),但跟1983-1984年度的相比降低程度不显著(P>0.05);空间β-多样性指数年变化趋向于"单峰"型,且4个年度的β-多样性指数值均无显著差异(P>0.05),只是年度平均值略有升高;1983-1984年度浮游植物多样性与生物量关系具有明显的规律性,即高多样性只发生在低生物量时,而且生物量高时多样性一定低,而其它3个年度未发现该规律;养殖区内外2站位的比较结果表明,扇贝养殖可一定程度地降低浮游植物α-多样性。     

桑沟湾磷循环

The phosphorus cycle is studied during 2013–2014 in the Sanggou Bay(SGB), which is a typical aquaculture area in northern China. The forms of measured phosphorus include dissolved inorganic phosphorus(DIP), dissolved organic phosphorus(DOP), particulate inorganic phosphorus(PIP), and particulate organic phosphorus(POP).DIP and PIP are the major forms of total dissolved phosphorus(TDP) and total particulate phosphorus(TPP),representing 51%–75% and 53%–80%, respectively. The concentrations and distributions of phosphorus forms vary among seasons relative to aquaculture cycles, fluvial input, and hydrodynamic conditions. In autumn the concentration of DIP is significantly higher than in other seasons(P0.01), and higher concentrations are found in the west of the bay. In winter and spring the phosphorus concentrations are higher in the east of the bay than in the west. In summer, the distributions of phosphorus forms are uniform. A preliminary phosphorus budget is developed, and shows that SGB is a net sink of phosphorus. A total of 1.80×10~7 mol/a phosphorus is transported into the bay. The Yellow Sea is the major source of net input of phosphorus(61%), followed by submarine groundwater discharge(SGD)(27%), river input(11%), and atmospheric deposition(1%). The main phosphorus sink is the harvest of seaweeds(Saccharina japonica and Gracilaria lemaneiformis), bivalves(Chlamys farreri),and oysters(Crassostrea gigas), accounting for a total of 1.12×10~7 mol/a. Burial of phosphorus in sediment is another important sink, accounting for 7.00×10~6 mol/a. Biodeposition by bivalves is the major source of phosphorus in sediment, accounting for 54% of the total.     

桑沟湾海水中营养盐分布及潜在性富营养化分析

根据2003年8月—2004年7月桑沟湾海区12个航次海水营养盐的调查资料,分析了该海区海水营养盐的分布特征及时空变化,评价了水质的潜在性富营养化状况。结果表明,溶解无机氮的年平均浓度为10.15μmol/dm3。4个季节中溶解无机氮以NO3-N为主要存在形式,占年平均含量的78.69%,其中以秋季的含量为最高。NH3-N占无机氮年平均含量的15.11%,NO2-N占无机氮年平均含量的6.20%。活性磷酸盐的年平均浓度为0.23μmol/dm3,浓度呈现春季较低和秋季较高的分布特征。活性硅酸盐的年平均浓度为2.86μmol/dm3,浓度呈现冬季较低和夏季较高的分布特征。DIN∶P,Si∶DIN和Si∶P的比值年平均分别为43.2,0.31和13.4,磷酸盐和硅酸盐为限制因素。与1983年在该海域所获数据比较发现,溶解无机氮的浓度是20年前的10.7倍,活性磷酸盐的浓度较20年前降低了43.9%,活性硅酸盐的浓度较20年前降低了34.1%。桑沟湾海区营养水平仍很低,总体上处于贫营养或中度营养化阶段,海水水质质量较好。     

桑沟湾溶存N2O的分布和海气交换通量的季节变化

于2006年4月至2007年1月对桑沟湾海域进行了4个航次的调查,采集表层海水样品,研究了该海域表层海水中溶解N_2O的分布特征及海气交换通量的季节变化,结果表明:桑沟湾表层海水中溶解N_2O浓度和饱和度存在一定的季节性变化,浓度表现为冬季最高而饱和度为夏季最高.利用Liss和Merlivat公式(LM86)以及Wanninkhof公式(W92)估算了该海湾海水中N_2O的年平均海-气交换通量,分别为0.2 μmol/(m~2·d)±0.1 μmol/(m~2·d)和1.5 μmol/(m~2·d)±1.0 μmol/(m~2·d).     

桑沟湾细菌的研究

在 3种培养基中用 MPN法按季对桑沟湾表层水和底质的总好气异养菌、几丁质降解菌、弧菌及其占总菌量比率等进行时空分布及变化的分析 ,并作了这些参数间的相关分析。估算了细菌生物量。评价了该湾的增养殖、生态和环境条件。指出了进一步对该湾做包括细菌在内的微生物学研究于健康水产增养殖业和保护生态环境的必要性     

2009年冬、夏季南海北部超微型浮游生物的分布特征及其环境相关分析

2009年2月(冬季)和8月(夏季)在南海北部海域(nSCS)采用流式细胞术对聚球藻、原绿球藻、超微型光合真核生物3类超微型光合浮游生物和异养浮游细菌的丰度和碳生物量的时空分布特征进行了研究,并分析了其与环境因子之间的关系。结果表明,夏季聚球藻和原绿球藻的平均丰度高于冬季,超微型光合真核生物和异养浮游细菌的丰度反之,为冬季高于夏季。聚球藻、超微型光合真核生物和异养浮游细菌在富营养的近岸陆架海域丰度较高,而原绿球藻高丰度则出现在陆坡开阔海域。在垂直分布上,聚球藻主要分布在跃层以上,跃层以下丰度迅速降低;原绿球藻高丰度主要出现在真光层底部;超微型光合真核生物在水层中的高值同样出现在真光层底部,且与Pico级份叶绿素a浓度分布一致;异养浮游细菌在水体中的分布与聚球藻类似。这些分布格局的差异,取决于环境条件的变化和4类超微型浮游生物生态生理适应性的差异。在超微型光合浮游生物群落中,各类群碳生物量的贡献因季节和海域类型的不同而发生变化:聚球藻在夏季近岸陆架区占超微型光合浮游生物总碳生物量的41%,原绿球藻在陆坡开阔海成为主要贡献者(50%),超微型光合真核生物碳生物量以冬季为高(在近岸陆架区占比68%)。冬、夏季异养浮游细菌碳生物量均高于超微型光合浮游生物碳生物量。     

Role of environment and hydrography in determining the picoplankton community structure of Sagami Bay,Japan

Seasonal variations in the picoplankton community were investigated from June 2002 to March 2004 within the photic zone of Sagami Bay, Japan. The study area was mostly dominated by coastal waters during the warm period (mixed layer water temperature ≥ 18°C). During the cold period (mixed layer water temperature ≤ 18°C), the water mass was characterized by low temperature and high saline waters indicative of the North Pacific Subtropical Mode Water (NPSTMW). Occasionally, a third type of water mass characterized by high temperature and low saline properties was observed, which could be evidence of the intrusion of warm Kuroshio waters. Synechococcus was the dominant picophytoplankton (5−28 × 10¹¹ cells m⁻²) followed by Prochlorococcus (1−5 × 10¹¹ cells m⁻²) and picoeukaryotes during the warm period. Heterotrophic bacteria dominated the picoplankton community throughout the year, especially in the warm period. During the Kuroshio Current advection, cyanobacterial abundance was high whereas that of picoeukaryotes and heterotrophic bacteria was low. During the cold period, homogeneously distributed, lower picophytoplankton cell densities were observed. The dominance of Synechococcus in the warm period reflects the importance of high temperature, low salinity and high Photosynthetically Active Radiation (PAR) on its distribution. Cyanobacterial and heterotrophic bacterial abundance showed a positive correlation with temperature. Prochlorococcus and picoeukaryotes showed a positive correlation with nutrients. Picoeukaryotes were the major contributors to the picophytoplankton carbon biomass. The annual picophytoplankton contribution to the photosynthetic biomass was 32 ± 4%. These observations suggest that the environmental conditions, combined with the seasonal variability in the source of the water mass, determines the community structure of picoplankton, which contributes substantially to the phytoplankton biomass and can play a very important role in the food web dynamics of Sagami Bay.     

海州湾大型底栖动物丰度和生物量的研究

2007年9月至2008年5月在海州湾采集15个站点的底泥样品,对大型底栖动物丰度和生物量进行调查研究。共采集到38种大型底栖动物,其中多毛类环节动物14种,甲壳动物5种,软体动物14种,棘皮动物1种,鱼类3种,扁形动物1种。春季平均生物量为3.3 g/m2,平均丰度为164个/m2;秋季平均生物量为26.8 g/m2,平均丰度为180个/ m2。本次调查与1959~1960年和2000~2001年南黄海的调查结果相比较,生物量有所下降。     

Community structure of picoplankton abundance and biomass in the southern Huanghai Sea during the spring and autumn of 2006

During spring and autumn of 2006,the investigations on abundance,carbon biomass and distribution of picoplankton were carried out in the southern Huanghai Sea(Yellow Sea,sHS) . Three groups of picoplankton-Synechococcus(Syn) ,Picoeukaryotes(PEuk) and heterotrophic bacteria(BAC) were identified,but Prochlorococcus(Pro) was undetected. The average abundance of Syn and PEuk was lower in spring(5.0 and 1.3 × 10 3 cells/cm 3,respectively) than in autumn(92.4 and 2.7 × 10 3 cells/cm 3,respectively) ,but it was opposite for BAC(1.3 and 0.7 × 10 6 cells/cm 3 in spring and autumn,respectively) . And the total carbon biomass of picoplankton was higher in spring(37.23 ± 11.67) mg/m 3 than in autumn(21.29 ± 13.75) mg/m 3 . The ratios of the three cell abundance were 5:1:1 341 and 30:1:124 in spring and autumn,respectively. And the ratios of carbon biomass of them were 5:7:362 and 9:4:4 in spring and autumn,respectively. Seasonal distribution characteristics of Syn,PEuk,BAC were quite different from each other. In spring,Syn abundance decreased in turn in the central waters(where phytoplankton bloom in spring occurred) ,the southern waters and inshore waters of the Shandong Peninsula(where even Syn was undetected) ;the high values of PEuk abundance appeared in the central and southern waters and the inshore of the Shandong Peninsula;the abundance of BAC was nearly three order of magnitude higher than that of photosynthetic picoplankton,and high values appeared in the central waters. In autumn,Syn abundance in central waters was higher than that in surrounding waters,while for PEuk abundance,it decreased in turn in the inshore waters of the Shandong Peninsula,the southern waters and the central waters;BAC presented a complicated blocky type distribution. Sub-surface maximum of each group of picopalnkton appeared in both spring and autumn. Compared with the available literatures concerning the studied area,the range of Syn abundance was larger,and the abundance of BAC was higher. In addition,the conversion factors for calculating picoplanktonic carbon biomass were discussed,with the conversion factors which are different from previous studies in the same surveyed waters. The result of regression analysis showed that there was distinct positive correlation between BAC and photosynthetic picoplankton in spring(r=0.61,P 0.001) ,but no correlation was found in autumn.     

东寨港红树林小型底栖动物的密度和生物量研究

2012年2月对海南省东寨港红树林滩涂沉积物小型底栖动物进行研究,结果表明,红树林中有六大类小型底栖动物,包括自由生活线虫、桡足类、涡虫、多毛类、寡毛类、海螨.在种类组成上,自由生活线虫为优势类群,在4个采样站位中,分别占小型底栖动物总数量的95.30％,97.02％,96.45％,90.53％.东寨港红树林小型底栖动物的总栖息密度为(1 082.23±563.76)个/(10 cm2),总生物量为(764.06±511.63)μg/(10 cm2).4个采样站位平均多样性指数H'分别为0.26、0.17、0.20、0.45,平均均匀度指数 J 分别为0.13、0.09、0.10、0.23.最小显著极差法(LSR)进行多重比较分析表明,4个采样点小型底栖动物差异明显.海洋线虫与桡足类的数量之比(N/C)显示东寨港红树林受到了有机质污染.