厦门西港浮游植物吸收磷酸盐的粒级特征

厦门西港微型浮游植物（3～20μm）吸收磷酸盐的百分比、吸收速率常数和单位体积吸收速率均最大，分别为74．85％、8．28×10-5／s和5．38×10-5μmol／（dm3·s），小型浮游植物（20～200μm）次之，超微型浮游植物（0．2～3μm）最小；单位叶绿素a的吸收速率是超微型浮游植物最大[5．38×10-5μmol／（μg·s）]，微型次之，小型最小。相关分析表明各粒级浮游植物吸收磷酸盐的百分比与相应粒级浮游植物的叶绿素a含量和光合速率的百分比呈良好的正相关关系。     

冬季南海北部海域微型浮游动物及其对浮游植物摄食压力研究

2009年1月在南海北部海域的5个站位,采用稀释法和显微分析技术研究了浮游植物生长率及微型浮游动物对浮游植物的摄食压力,同时测定了微型浮游动物的丰度及类群组成.结果表明:南海北部微型浮游动物类群主要以无壳纤毛虫为主,南海北部微型浮游动物类群细胞丰度为33～529个/dm3.南海北部浮游植物生长率为0.45～1.83 d-1,微型浮游动物摄食率为0.44～1.76 d-1,摄食压力占浮游植物现存量的42.6%～82.8%,占初级生产力的97.3%～225.1%.近岸区摄食压力比陆架区高,表明冬季南海近岸区微型浮游动物摄食能够有效的控制浮游植物的生长,而陆架区浮游植物生长率大于摄食率,浮游植物存在着现存量的积累,微型浮游动物并不能完全控制浮游植物的生长.     

南极普里兹湾浮游植物现存量与初级生产力粒级结构和新生产力研究

报道1998～1999年夏季在南极普里兹湾及其毗邻海域对细胞丰度、优势种类组成、生物量和初级生产力的粒级结构、新生产力及其环境制约机制的研究.结果表明,调查海区具有显著的空间区域化特征.普里兹湾及其毗邻陆架区浮游植物现存生物量和生产力均较高,大陆坡和深海区明显降低;营养盐浓度由于浮游植物的消耗则有相反的分布趋势.浮游植物生物量和生产力受水体的垂直稳定度、浮游动物摄食、水温和光照等环境条件的控制.粒度分级测定结果表明,对调查海区叶绿素a的贡献,小型浮游生物为52.2%,微型为29.4%,微微型为18.4%;对初级生产力的贡献,小型为52.4%,微型为28.7%,微微型为18.9%.研究海区的平均新生产力和f比分别为230.6mg/(m2·d)和0.43.     

杭州湾——舟山渔场秋季浮游植物现存量和初级生产力

1995年9月在杭州湾和长江口至舟山海区进行了浮游植物细胞丰度、叶绿素a浓度和初级生产力的现场观测研究.结果表明,表层水浮游植物平均细胞丰度为(22.68±63.33)×104个/dm3;平均叶绿素a浓度为2.80±3.46μg/dm3,小于20μm的微型和微微型浮游生物细胞对叶绿素a的贡献占71%;平均初级生产力(C)为692.5±1192.4mg/(m2·d),小于20μm的微型和微微型浮游生物细胞对总生产力的贡献占68%.河口区悬浮物质浓度高,浮游植物光合作用受光的限制,各项生物参数与真光层深度紧密相关.生物锋区位于真光层深度10～20m、盐度26～32的长江冲淡水稀释区.同时探讨了浮游植物细胞活性(R)与光合作用同化数(AN)、叶绿素a与初级生产力、叶绿素a与海面光谱反射率的相互关系,为海洋水色遥感在初级生产力的应用研究提供科学依据     

渤海中部和渤海海峡及其邻近海域浮游植物粒级生物量的初步研究 Ⅰ.浮游植物粒级生物量的分布特征

对1998年9月和1999年4月在渤海(37°～41°N,117.5°～122.5°E)进行的两次生态系统综合外业调查,对蓬莱、长岛两地进行15个月的连续资料监测,对渤海调查区浮游植物粒级生物量的平面分布、垂直分布、昼夜变化和周年变化特征进行了研究.结果表明,秋季主要以小型浮游植物为主,然后依次为微型和微微型浮游植物;春季主要以微型浮游植物所占比重最高,其次为小型浮游植物,微微型浮游植物占比例最低.1998年秋季对断面1,2浮游植物粒级组分的垂直分布研究表明,在不同海区(调查区西部、南部、渤海中部和渤海海峡)的不同水层,浮游植物粒级生物量的分布有明显差异.潮汐对浮游植物粒级生物量的周日变化影响较大.蓬莱、长岛两地的连续调查资料表明,浮游植物各粒级组分除微微型浮游植物外1a有两个峰.网采浮游植物在4和7月有高峰,4月是主峰;小型网采浮游植物在6和11月有高峰,6月是主峰;微型浮游植物在4和11月有高峰,两峰值接近;微微型浮游植物在9月有高峰.调查区与其他海区浮游植物叶绿素a浓度粒级组分比较,表明小型浮游植物所占比重较大.     

厦门海域小型浮游动物和桡足类的摄食对浮游植物生长的影响

2005年11月16日和27日,运用稀释法和桡足类添加法,对厦门宝珠屿海域小型浮游动物及桡足类的摄食对浮游植物生长的影响进行了研究.结果表明,各粒级浮游植物的生长率均大于小型浮游动物的摄食率,小型浮游动物对总的Chla和nano-Chla具有一致的显著的摄食作用(0.51～0.78d-1),当存在螺旋环沟藻等大型的异养甲藻时,亦能摄食micro-级浮游植物.所添加的桡足类主要摄食micro-级的浮游植物,也显著摄食小型浮游动物,16日,所添加的桡足类促进nano-级浮游植物的每天生长效应达0.03ind/dm3.说明了厦门海域小型浮游动物及桡足类的摄食共同控制着浮游植物的生长,由于桡足类的杂食性,可产生一定的营养级联效应.     

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

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．     

南极普里兹湾边缘浮冰区微型浮游动物的摄食及其氮的排泄

于1998–1999年夏季在南极普里兹湾边缘浮冰区利用稀释培养实验进行了微型浮游动物对浮游植物的摄食现场实验研究,同时对微型浮游动物的氨氮产生率进行了推算。结果表明,微型浮游动物的日摄食量为5.1–25.0mgC/(m³*d),占浮游植物现存量的10%–65%,对初级生产力的摄食压力也较大(34%–100%)。利用微型浮游动物的摄食率推算得出其氮产生率为0.44–1.75mg/(m³*d),达到维持现场初级生产所需氨氮的68%–536%。由此可见,微型浮游动物在南极夏季边缘浮冰区海洋生态系统中,特别是对浮游植物的生产和归宿起着十分重要的调控作用。     

厦门杏林虾池夏冬季微型浮游动物对浮游植物的摄食压力

20 0 0年 8月和 2 0 0 1年 2月 ,在杏林虾池用稀释法研究了微型浮游动物对浮游植物的摄食压力 .结果表明 :砂壳纤毛虫、甲壳类无节幼体是微型浮游动物的优势种 ;浮游植物生长率夏季为 0 .40～ 1 .0 1 /d、冬季为 0 .1 8～ 0 .96/d ;浮游动物的摄食率夏季为 0 .578～ 1 .3 2 4/d、冬季为 0 .2 0 4～ 0 .2 55/d ;日摄食率 (以C计 )夏季为 1 9.1 7～89.51mg/(m3·d)、冬季为 3 .3 2～ 7.2 3mg/(m3·d) ,各占浮游植物现存量的 43 .90 %～ 73 .40 %、1 8.43 %～ 2 2 .51 %;对初级生产力的摄食压力夏季为 1 1 5.2 3 %～1 93 .52 %、冬季为 3 7.47%～ 1 1 1 .3 1 %.     

亚热带和热带环境下夜光藻的摄食压力

2015年以广西三娘湾海域为亚热带海区,三亚海域为热带海区,利用稀释法开展了现场培养实验,测定热带和亚热带海区夜光藻对浮游植物、微型浮游动物对浮游植物的摄食压力,研究了夜光藻对不同粒径的浮游生物的摄食作用.结果表明:两个海区都有比较高的生长率和摄食率,其中细菌有最高的生长率和摄食死亡率;夜光藻的摄食率,从总浮游植物、微微型浮游植物到聚球藻、细菌逐渐增高.亚热带海区与热带海区相比,微型浮游动物的摄食压力更小,表明低温影响了浮游动物的摄食活性;而营养盐是引起亚热带海区高生长率的主要因素.     

台湾海峡小型浮游动物的摄食对夏季藻华演替的影响

于2004年8月1~6日对台湾海峡南部近岸的藻华过程进行了定点连续跟踪观测,用稀释法研究了浮游植物的生长率和小型浮游动物对浮游植物的摄食死亡率,同时运用高效液相色谱(HPLC)技术,分析了浮游植物不同光合色素类群的生长率和摄食死亡率.结果表明,观测期间处于藻华的消退期.8月1日时,浮游植物生物量(叶绿素a)和丰度分别为2.04μg/dm3和2.99×105个/dm3,主要优势种为尖刺伪菱形藻(Pseudo-nitzschia pungens)、冰河拟星杆藻(Asterionellopsis glacialis)和中肋骨条藻(Skeletonema costatum),8月6日时,浮游植物生物量和丰度分别减为0.37μg/dm3和1.54×104个/dm3;而蓝藻和甲藻的丰度和比例则呈现出逐渐增加的趋势,所占的比重分别从1日的0.04%和0.85%增加到6日的9.59%和41.97%.小型浮游动物主要由无壳纤毛虫、砂壳纤毛虫、红色中缢虫(Mesodinium rubrum)和异养甲藻等类群组成,总丰度于8月2日达到最大值,为3640个/dm3,之后逐渐减少,6日时,仅为436个/dm3.观测期间,小型浮游动物在群落组成上虽一直以无壳纤毛虫和异养甲藻为主,但在具体的类群结构上却表现出了一定的差异,30μm以下的无壳纤毛虫和异养甲藻总体呈下降的趋势,而红色中缢虫、砂壳纤毛虫和大于50μm的无壳纤毛虫总体呈增加的趋势.观测期间,浮游植物的生长率为0.40~0.91d-1,小型浮游动物的摄食率为0.26~1.34d-1,摄食率和生长率总体呈逐渐下降的趋势.结果还表明,小型浮游动物的摄食率与叶绿素a具有很好的相关性(R2=0.89),对各光合色素类群的现存量和初级生产力均具有较高的摄食压力(分别为37.97%~82.24%和70.71%~281.33%),是藻华消亡的重要原因之一;此外,小型浮游动物对甲藻和蓝藻的避食行为,可能是观测期间由“硅藻”水华向“硅藻-甲藻”水华转变的重要原因之一.     

Seasonal variability in plankton food web structure and trophodynamics in the neritic area of Sagami Bay,Japan

The plankton food web structure and trophodynamics in the neritic area of Sagami Bay were investigated from January 2003 to December 2005, based on abundance, biomass, production rate and nutritional requirements of pico- (0.2–2 μm), nano- (2–20 μm), micro- (20–200 μm) and mesoplankton (>200 μm: mainly copepods CI-CVI) at 0–10 m depth. The average carbon biomass of the total plankton community was higher in spring and summer (1.452 and 1.466 g C m⁻², respectively) than in winter and autumn (0.676 and 0.686 g C m⁻², respectively). The average values of primary production and of production rate and food requirement of heterotrophic organisms were higher in summer than in other seasons. During the study period the biomass, production rate and food requirement of small heterotrophs (i.e. bacteria: BA; heterotrophic nanoflagellates: HNF; microzooplankton: MZ) were much higher than those of copepod secondary (CSP) and tertiary producers (CTP), indicating that the microbial food web was the main route of carbon flow from phytoplankton (PP) to CSP and CTP, rather than the grazing food chain. In particular, during summer and autumn the biomass of pico- and nano-size PP plus BA was greater than that of micro-size PP, suggesting the high prevalence of the microbial food web (pico-/nanophytoplankton/BA-HNF/MZ-copepods). During winter and spring, the biomass of micro-size PP was greater than that of pico- and nano-size PP plus BA, suggesting that the indirect route (microphytoplankton-MZ-copepods) probably prevailed, while the microbial food web might be important.     

Seasonal Variations of Plankton Food Web Structure in the Coastal Water off Usujiri Southwestern Hokkaido,Japan

The planktonic food web structure in the subarctic coastal water off Usujiri south-western Hokkaido, Japan was investigated from June 1997 to June 1999, based on seasonal biomass data of pico- (<2 µm), nano- (2–10 µm), micro- (10–200 µm) and mesoplankton (>200 µm), and path analysis using the structural equation model (SEM). In spring, microphytoplankton predominated due to diatom bloom, while pico- and nanophytoplankton predominated in the other seasons, except November and December 1997. The seasonal change in size distribution of heterotrophic plankton was almost similar to that of phytoplankton, and mesozooplankton biomass was high in spring. The path analyses suggest that the main channel in the microbial food web could vary according to phytoplankton size composition, indicating not only the classical food chain (microphytoplankton - copepods) but also the indirect route (microphytoplankton - naked dinoflagellates - copepods).     

Distribution and Feeding of Herbivorous Zooplankton in the Laptev Sea

Sampling was conducted along the quasi meridional transect at 130° E from the Lena River estuary to northern deep-sea regions of the Laptev Sea in September 2015. The latitudinal zonality and the impact of river runoff are manifested in the temperature and salinity distribution, concentration of particulate organic matter, and the structure of plankton communities. The differences in the chl a concentration and primary production along the transect are insignificant. The feeding rate of mesozooplankton herbivores was assessed by a fluorescence technique. The total consumption of phytoplankton biomass and primary production are estimated based on the feeding rate, abundance of zooplankton species, and their diel migrations. The daily grazing impact of zooplankton on phytoplankton biomass increases from 2% on the inner shelf to 3% on the mid-shelf, 5% on the outer shelf, and 10% in the deep-sea part of the basin. The consumption of primary production also increases: 1, 4.5, 5.7, and 13.9%, respectively. In the fall, the consumption of phytoplankton does not compensate the energy demands for respiration. The latitudinal zonality of the Laptev Sea appears not only in the hydrophysical water parameters and the structure of plankton communities, but also in their functional characteristics.     

Abundance, Biomass, Production and Trophic Roles of Micro- and Net-Zooplankton in Ise Bay, Central Japan, in Winter

We investigated the geographical variations in abundance and biomass of the major taxonomic groups of micro- and net-zooplankton along a transect through Ise Bay, central Japan, and neighboring Pacific Ocean in February 1995. The results were used to estimate their secondary and tertiary production rates and assess their trophic roles in this eutrophic embayment in winter. Ise Bay nourished a much higher biomass of both micro- and net-zooplankton (mean: 3.79 and 13.9 mg C m^–3, respectively) than the offshore area (mean: 0.76 and 4.47 mg C m^–3, respectively). In the bay, tintinnid ciliates, naked ciliates and copepod nauplii accounted for, on average, 69, 18 and 13% of the microzooplankton biomass, respectively. Of net-zooplankton biomass, copepods (i.e. Acartia, Calanus, Centropages, Microsetella and Paracalanus) formed the majority (mean: 63%). Average secondary production rates of micro- and net-zooplankton in the bay were 1.19 and 1.87 mg C m^–3d^–1 (or 23.1 and 36.4 mg C m^–2d^–1), respectively, and average tertiary production rate of net-zooplankton was 0.75 mg C m^–3d^–1 (or 14.6 mg C m^–2d^–1). Available data approximated average phytoplankton primary production rate as 1000 mg C m^–2d^–1 during our study period. The transfer efficiency from primary production to zooplankton secondary production was 6.0%, and the efficiency from secondary production to tertiary production was 25%. The amount of food required to support the zooplankton secondary production corresponded to 18% of the phytoplankton primary production or only 1.7% of the phytoplankton biomass, demonstrating that the grazing impact of herbivorous zooplankton was minor in Ise Bay in winter.     

Fatty Acid Composition and Community Structure of Plankton from the San Lorenzo Channel, Gulf of California

The structure of the plankton community and fatty acid composition of nano-, micro- and zooplankton are described during four seasons of 1994 from the San Lorenzo Channel. During August, the warmest temperature in the surface water was observed and a thermocline developed between 20 and 30 m. In the remaining months, a well-mixed layer occurred in the upper 30 m. The chlorophyllacontent of the nanoplankton fraction (<38 μm) was higher than the microplanktonic fraction (38–200 μm) year round. Maximal chlorophyll values (1·5–3 μ l⁻¹) occurred in January, which may be associated with organic matter, since phytoplankton was lower than at other seasons. The relative abundance of diatoms increased from January (57% of phytoplankton) to November (99%). The increment was mainly due toNitzschiaandChaetoceros. Dinoflagellates were always low (0·03–1·36 cells ml⁻¹). Copepods (mainlyEucalanus) dominated the zooplankton in winter and fall, while in spring and summer, the abundance of doliolids was similar to the copepods (Nannocalanus minordominated).Four fatty acids (16:0, 16:1, 18:0, 18:1) were the most conspicuous in the plankton, representing usually between 40 and 80% of the total fatty acids throughout the water column. In winter, higher fatty acid content and higher relative amounts of 16:0 and 16:1 were observed than in the warm months. Stearic acid (18:0) peaked during fall. The major seasonal differences occurred in the nanoplankton, which had peaks of 20:5 during January, and 16:4 in April. A strong decrease in polyunsaturated fatty acids (PUFA) occurred during the warm months. The fatty acid composition of microplankton and larger zooplankton was similar in winter–spring. Individual copepods of selected species (Eucalanus sewelli,Rhincalanus nasutus,Centropages furcatusandLabidocera acuta) showed fatty acid profiles similar to the mixed zooplankton, with some differences in content of PUFA.     

Major contribution from mesopelagic plankton to heterotrophic metabolism in the upper ocean

Measurements of plankton respiration and heterotrophic bacterial abundance and production were made at seven deep water stations within the upper 500 m of the Gulf of Mexico during the summer of 1995. Bacterial abundance [(1.1–4.6)×108 1⁻¹] and rates of bacterial production (2–19 nM C h⁻¹) and plankton respiration (50–245 nM O₂ h⁻¹) decreased with depth by four- to nine-fold, and were similar to those reported for oligotrophic waters. Bacterial turnover times increased with depth from approximately 1 to 5 days. Bacterial growth efficiencies decreased from 15% at the surface to 8% at 500 m. Depth-integrated plankton respiration exceeded known estimates of primary production for the region, suggesting that heterotrophic utilization of previously and concurrently produced organic matter (e.g. spring phytoplankton growth, and summer blooms of Trichodesmium sp.) was occurring during the summer. Estimates for the upper 500 m showed that roughly half of the bacterial biomass (56%), bacterial production (49%), and plankton respiration (60%) occurred below the euphotic zone. Routine oceanographic studies have focused exclusively on the metabolic activity occurring within the euphotic zone. Our measurements, however, indicate that mesopelagic plankton also contribute substantially to heterotrophic metabolism and nutrient cycling in the ocean.     

北冰洋楚科奇海浮游细菌丰度和生产力及其分布特征

2012年夏季中国第5次北极科学考察期间,对北冰洋楚科奇海及其北部边缘海浮游细菌丰度和生产力进行了测定,并将其与环境因子进行了相关性分析。结果显示,楚科奇海浮游细菌丰度的变化范围为0.56×108~6.41×108 cells/dm3,平均为2.25×108 cells/dm3;细菌生产力介于0.042~1.92mg/(m3·d)(以碳计)之间,平均为0.54mg/(m3·d)(以碳计),与已有研究结果基本相当。陆架区细菌丰度和生产力要明显高于北部边缘区,但前者的单位细菌生产力则较低。与环境因子的相关性分析显示,细菌丰度与温度和叶绿素a浓度存在显著正相关(p0.01),表明北极变暖导致的海水升温及浮游植物生物量的增加均会促进细菌的生长,从而进一步提高细菌在海洋生态系统和碳循环中的作用。但陆架区的细菌生产力与环境参数均没有显著相关性,表明其影响因素较为复杂;生产力在北部边缘区则仅与叶绿素a存在显著正相关(p0.01),表明浮游植物生长过程产生的溶解有机碳(DOC)是细菌生长最为主要的碳源,碳源的单一可能制约细菌的生产从而导致该海域无冰状态下细菌丰度的增加不如预期,但融冰过程带来的大量DOC将促进细菌活性的增加。