夏季西南印度洋叶绿素a分布特征

分析了2011年1月西南印度洋叶绿素a的分布特征及其粒级结构,并结合水动力学环境和营养盐数据探讨了其主要影响因素。结果表明,西南印度洋副热带涡流(IOSG)区表层叶绿素a浓度较低,不超过0.07 mg/m3,次表层叶绿素a浓度最大值所在水层较深,超过100 m;副热带聚集区(SCZ)表层叶绿素a浓度较高(0.164—0.247 mg/m3),次表层叶绿素a浓度最大值出现在50—70 m层。硝酸盐是该海区浮游植物生长的主要限制因素。微微型(pico)粒级的浮游植物占绝对优势,所有站位其对总叶绿素a的平均贡献率为71.1%,微型(nano)粒级次之(24.2%),小型(net)粒级所占比例最小(4.7%),其中IOSG区pico粒级对总叶绿素a的平均贡献率为77.9%,SCZ的pico粒级对总叶绿素a的平均贡献率为66.7%。IOSG区和SCZ海区之间水动力学环境的不同,可能导致了这两个海区叶绿素a的分布特征及粒级结构的较大差异。     

獐子岛及邻近海域秋季浮游植物的粒级结构及其影响因素

于2015年10月对獐子岛及邻近海域进行了航次调查,研究了獐子岛及邻近海域浮游植物粒级结构的空间分布特征及其环境影响因素。结果表明,秋季表层总叶绿素a、小型(20μm)、微型(2—20μm)和微微型(0.45—2μm)浮游植物叶绿素a浓度的范围分别为0.52—1.25、0.03—0.81、0.33—0.91、0—0.09μg/L,平均叶绿素a的浓度分别为0.76、0.19、0.53、0.03μg/L,对叶绿素a总量的贡献率分别为23.77%、72.26%和3.98%;底层总叶绿素a、小型(20μm)和微型(2—20μm)浮游植物叶绿素a浓度的范围分别为0.14—1.5、0.04—1.04、0.08—0.47μg/L,平均叶绿素a的浓度分别为0.46、0.22、0.24μg/L,对叶绿素a总量的贡献率分别为41.46%、58.50%。从垂直分布上来看,总叶绿素a浓度垂直变化为,表层底层;小型浮游植物垂直分布较为均匀;微型浮游植物垂直变化为,表层底层;微微型浮游植物垂直变化为,表层底层,且在表、底层均保持较低水平。秋季表层微型浮游植物(2—20μm)浓度与盐度呈正相关。底层总叶绿素a浓度与磷酸盐浓度呈正相关,小型浮游植物(20μm)浓度与磷酸盐和硅酸盐浓度均表现为正相关,微型浮游植物(2—20μm)浓度与温度呈正相关。统计分析结果表明,温度、盐度、磷酸盐及硅酸盐浓度是影响獐子岛及邻近海域秋季浮游植物粒级结构变动的重要因素。     

东海赤潮高发区春季叶绿素a和初级生产力的分布特征

2002年4-5月对东海海域进行了综合调查,分析了海区叶绿素a和初级生产力的分布特性．结果表明,大面站表层平均叶绿素a浓度为1．086mg·m-3．分级叶绿素a结果显示．春季东海浮游植物以微型和微微型(<20μm)占优势,其对海区叶绿素a的贡献为64％,超微型浮游植物(<5μm)占浮游植物生物量的27％．营养盐分布和浮游动物的摄食压力影响了叶绿素a及其粒级结构的分布．平均初级生产力为10．091mg·m-3·h-1。赤潮跟踪的R-03、RL-01、RG-01站的平均初级生产力为399．984mg·m-3·h-1．光和营养盐成为叶绿素和初级生产力平面分布的主要限制因子．表层叶绿素a和初级生产力均在调查海区的123·E纵断面冲淡区产生高值区．DC-11站浮游植物生物量异常高,表层叶绿素a达到9．082mg·m-3,初级生产力为128．79mg·m-3·h-1．但并未出现水色异常．     

獐子岛海域冬季分级叶绿素a的分布特征及其影响因素

于2016年1月对獐子岛海域进行了航次调查,研究了獐子岛海域浮游植物粒级结构的空间分布特征及其环境影响因素。结果表明:冬季表层总叶绿素a、小型(20μm)、微型(2~20μm)和微微型(0.45~2μm)浮游植物叶绿素a浓度的范围分别为0.24~0.92、0.15~0.58、0.09~0.46、0~0.03μg·L-1,平均叶绿素a的浓度分别为0.69、0.36、0.33、0.002μg·L-1,小型、微型和微微型浮游植物对浮游植物总量的贡献率分别为51.72%、48.01%、0.26%;底层总叶绿素a、小型、微型和微微型浮游植物叶绿素a浓度的范围分别为0.29~1.77、0.12~1.45、0.17~0.50、0μg·L-1,平均叶绿素a的浓度分别为0.78、0.43、0.34、0μg·L-1,小型、微型和微微型浮游植物对浮游植物总量的贡献率分别为52.97%、47.03%、0;从垂直分布上来看,表、底层总叶绿素a及两种粒级浮游植物(20μm、2~20μm)的浓度均差异不显著,分布较为均匀;从水平分布上来看,总叶绿素a及两种粒级浮游植物(20μm、2~20μm)浓度的表、底层空间分布趋势相近,均呈现出由獐子岛海域西北部向南部逐渐降低的趋势。RDA分析表明,温度、盐度、溶解氧、颗粒态有机物、NO2--N和NH4+-N是影响獐子岛海域冬季浮游植物粒级结构变动的重要因素。     

长江口冬季和春季浮游植物的粒级生物量

根据2005年2月28日—3月10日和5月30日—6月4日在长江口及其邻近水域进行的多学科综合外业调查,报道了冬季和春季浮游植物粒级生物量的空间分布和组成特征,并探讨了影响浮游植物粒级生物量的环境因子.结果表明：冬季长江口及其邻近水域表层叶绿素a平均浓度为1.28 mg·m^-3,高值区集中在口门附近;小粒径浮游植物（<20 μm）对浮游植物生物量的贡献率为66.7%,但在冲淡水区大粒径浮游植物（>20 μm）占据优势.春季长江口及其邻近水域表层叶绿素a浓度大幅增加,口门内、外的平均值分别为0.67和6.03 mg·m^-3,122.5°—123.0° E间水域因水华爆发出现显著的叶绿素a高值区;小粒径浮游植物对浮游植物生物量的贡献高达83.5%,其优势在水华区尤为明显.典型站位浮游植物粒级生物量的垂向分布显示,2种粒径浮游植物叶绿素a浓度的差异随水深增加而减小,至底层二者浓度相当.根据所获的环境因子资料,盐度和营养盐是影响长江口及其邻近水域浮游植物粒级生物量分布和组成的重要环境因子.     

基于光合色素的钦州湾平水期浮游植物群落结构研究

应用反相高效液相色谱(RP - HPLC) 并结合二极管阵列检测器分析技术,分析了2010年平水期钦州湾浮游植物光合色素组成,进而由CHEMTAX 软件估算全粒级浮游植物的群落结构。结果表明：平水期浮游植物特征光合色素含量以岩藻黄素最高,其次为叶绿素b、玉米黄素和青绿素,其它特征光合色素含量较低;水体中色素组成表明浮游植物的优势类群为硅藻,其次为蓝藻和青绿藻,它们分别平均占据了浮游植物生物量的73.9%、11.7%和8.7%,其它藻类所占比例很低。硅藻呈现出从湾顶往外随着盐度增加而增加的趋势,而青绿藻显现出相反的分布趋势。钦州湾浮游植物群落结构形成了茅岭江和钦江河口、湾颈-外湾近岸和外湾靠外海域共三种类型,平水期浮游植物群落结构的组成和分布特征主要是由茅岭江和钦江径流变化以及营养盐等环境所决定。平水期叶绿素b和青绿素在大部分站点存在证实了青绿藻在钦州湾的分布,而且表明青绿藻、绿藻和定鞭金藻等微型藻类在钦州湾占有相当比重,它们的重要性有待进一步研究。     

桑沟湾春季叶绿素a浓度分布及其影响因素

依据2014年5月走航和定点连续调查资料,分析了桑沟湾叶绿素a的空间分布及昼日变化特征,结合理、化环境因素的相关性分析,探讨影响叶绿素a浓度的主要因素。(1)走航调查的结果显示,桑沟湾春季叶绿素a浓度较低,叶绿素a浓度范围为0.11—1.40μg/L,平均为(0.64±0.36)μg/L。叶绿素a浓度从湾内向湾外逐步降低,贝类区混养区海带区外海区;湾内表层叶绿素a浓度均高于底层,而湾外的非养殖区则相反(2)网箱区叶绿素a浓度最高,日平均为1.70μg/L,显著高于其它3个区;海草区最低,为0.57μg/L,与海带养殖区无显著性差异,显著低于贝类养殖区和网箱区。叶绿素a浓度的总体趋势为:网箱区贝类区海带区和海草区。而且,不同养殖区域,叶绿素a浓度昼夜变化规律各不相同,反映了养殖活动的影响。海草区白天表层高于底层,而夜间则相反;网箱区底层均高于表层;贝类区表层均高于底层;海带区表底层叶绿素a浓度呈现出升降交替的规律。(3)叶绿素a浓度与硅酸盐、水温显著正相关,与其他环境因子,如氨氮、亚硝酸盐、磷酸盐等无显著相关性。硅酸盐和温度可能为影响桑沟湾春季浮游植物生长的主要限制性因素。(4)桑沟湾春季浮游植物生长受多重因素的限制,湾内营养盐浓度与叶绿素a浓度并未呈现显著的规律性,营养盐的上行控制和贝类摄食的下行控制均能影响浮游植物的生长。     

粒径分级叶绿素a对富营养水体生物修复的响应

通过对富营养小水体叶绿素 a分粒级分析 ,探讨了生态修复对水体粒径分级叶绿素 a的影响以及各粒级叶绿素 a对修复的响应 ,Nano-粒级叶绿素 a为本水体的第 1贡献者 ,Net-粒级也占有较高的比例 ,处于第 2位 ,Pico-粒级所占份额最小 ;环境因子 BOD5和 TN/TP与 Net- Chla%和 Nano- Chla%分别呈非常显著负和正相关 ;生物修复实施前后 Net- chla%和 Nano- chla%均有非常显著变化 ,生态修复工程后网采浮游植物相对生物量明显增多 ,微型浮游植物相对生物量显著减少 ,而微微型浮游植物相对生物量仅有小幅度的升高 ,修复前后并无显著差异     

应用光合色素研究广西钦州湾丰水期浮游植物群落结构

通过2010年6月现场航次19个站点的调查,应用反相高效液相色谱(RP - HPLC) 并结合二极管阵列检测器分析技术,分析了丰水期广西钦州湾浮游植物光合色素组成,进而由CHEMTAX 软件估算全粒级浮游植物的群落结构。结果表明,钦州湾浮游植物光合色素含量以叶绿素a最高,其次为岩藻黄素;浮游植物的优势类群为硅藻,其次为蓝藻和青绿藻,它们分别平均占据了浮游植物生物量的70.2%、12.6%和9.4%,而其它藻类除了绿藻茅岭江河口占据较高的比例(40.2%)之外在其它站点所占比例很低。钦州湾浮游植物群落结构形成了茅岭江口、内湾、外湾和湾外近海共四种类型,茅岭江口以绿藻为优势类群,内湾以硅藻、蓝藻和青绿藻为主要优势类群,外湾以硅藻为单一优势类群,湾外相对于外湾硅藻比重略为下降。主要光合色素含量及浮游植物类群生物量的分布特征与盐度、营养盐关系密切,浮游植物群落结构的分布变化主要受径流及其输入导致的营养盐变化的影响,而这种影响导致了内湾和外湾之间浮游植物主要类群的生物量多寡及浮游植物群落结构的差异。     

南海北部海区浮游植物粒级结构生物光学反演模型的验证与评价

浮游植物粒级结构是海洋生态系统中的一个重要生物学因子。基于生物光学参数反演浮游植物粒级结构变化是当前水色遥感研究的热点问题。本文综合南海北部海区多年航次调查数据,对现有几类反演算法进行了区域性优化和验证评价。根据叶绿素 a 浓度（Chl a）或浮游植物吸收系数（aph （443））的阈值可实现南海北部海区小型（Micro）和微微型（Pico）浮游植物主导的划分,微型（Nano）的判别精度较差。基于归一化吸收光谱提取的粒级指数可定性地表征浮游植物粒级结构的综合变化趋势。基于叶绿素 a 浓度的三组分模型,较好地模拟浮游植物粒级结构的变化规律,可实现分粒级叶绿素 a 浓度的定量反演,Pico 粒级的反演精度较高;在此基础上,耦合浮游植物吸收光谱变化规律和总叶绿素 a 浓度定量反演粒级结构的模型,进一步提高了 Micro 和Nano 粒级的反演精度,且线性相关程度增强。     

Peculiarities of summer phytoplankton spatial distribution in Onega Bay of the White Sea under local hydrophysical conditions

The species composition and phytoplankton biomass, concentrations of chlorophyll “a” (Chl) and nutrients in the surface water layer, and accompanying hydrophysical conditions were studied in Onega Bay of the White Sea in June 2015. The temperature and salinity of surface water layer and the water column stability varied greatly in the bay. The nutrients' concentrations exceeded the limiting threshold necessary for the phytoplankton development. The phytoplankton abundance was relatively low, averaged as 13.46 ± 9.00 mg C/m³ (total phytoplankton biomass), 0.78 ± 0.43 mg/m³ (concentration of chlorophyll “a”), and 0.18 ± 0.27 mg C/m³ (picophytoplankton biomass). The highest phytoplankton biomass has been registered along the frontal zones. Three phytoplankton communities that differed significantly in their structure have been found.     

Size-fractionated productivity and nutrient dynamics of phytoplankton in subtropical coastal environments

It is now well established that the size distribution of phytoplankton plays an important role in primary production processes and nutrient dynamics of coastal environment. In situ observations showed that nanophytoplankton (3–20 μm) contributed 72.08% and58.18% of phytoplankton biomass and 58.32% and 41.14% of primary productivity to Xiamen Western Waters and the northern Taiwan Strait, respectively; picophytoplankton (0.2–3 μm) dominated the biomass (64.70%) and productivity (66.09%) in the southern Taiwan Strait. Furthermore, nanophytoplankton accounted for 75% of phosphate uptake with the highest rate constant (8.3×10^-5 s^-1) and uptake rate in unit water volume (5.4×10^-5 mmol dm^-3s^-1); picophytoplankton had the highest uptake rate in unit biomass (5.4×10^-5 mmol mg^-1s^-1) and photosynthetic index (3.8 mgC mgChl a^-1h^-1). All the results highlighted the remarkable characteristics of small size ranged (0.2–20 μm) phytoplankton in subtropical coastal environments: main contributor to phytoplankton biomass and production, high efficiency on organic carbon production and nutrient recycling. The far reaching environmental and ecological implications were discussed. This revised version was published online in August 2006 with corrections to the Cover Date.     

Size-fractionated Primary Production in the South Atlantic and Atlantic Sectors of the Southern Ocean

Results are presented from size fractionated chlorophyll a (Chla) and primary production studies along a transect between Antarcticaand southern Africa during the second South African AntarcticMarine Ecosystem Study (SAAMES II), conducted in late australsummer (January to February) 1993. Total integrated Chl a alongthe transect was highest in the vicinity of the Marginal IceZone (MIZ) and Antarctic Polar Front (APF). At these stations,integrated Chl a biomass was always >25 mg Chl a m^–2and was dominated by microphytoplankton. Although nominal increasesinChl a biomass were also associated with the Subantarctic Front(SAF) and Subtropical Convergence (STC), total Chl a biomassin these regions was dominated by nanophytoplankton. Withinthe inter-frontal regions, total integrated Chl a biomass waslower, generally <25 mg Chl a m^–2, and was always dominatedby nanophytoplankton. An exception was found in the AgulhasReturn Current (ARC) where picophytoplankton dominated. Totaldaily integrated production along the transect ranged between60 and 436 mg C m^–2 day^–1. Elevated production rateswere recorded at stations occupied in the vicinity of the MIZand at all the major oceanic frontal systems. The contributionsof the various size fractions to total daily production displayedthe same spatial pattern as integrated biomass, with microphytoplanktonbeing the most important contributor in areas characterizedby elevated phytoplankton biomass. Outside these regions, nanophytoplanktondominated the total phytoplankton production. Again, an exceptionwas found in the ARC north of the STC where picophytoplanktondominated total production. There, the lowest production alongthe entire transect was recorded, with total daily integratedproduction always <90 mg C m^–2 day^–1. The increasedproduction rates recorded in the MIZ appeared to result fromincreased water column stability as indicated by a shallow mixed-layerdepth. Within the inter-frontal regions, the existence of adeep mixed layer appeared to limit phytoplankton production.Low silicate concentrations in the waters north of the APF mayalso have limited the growth of large microphytoplankton.     

Fast microzooplankton grazing on fast-growing,low-biomass phytoplankton: a case study in spring in Chesapeake Bay,Delaware Inland Bays and Delaware Bay

Dilution experiments were performed to examine the growth and grazing mortality rates of picophytoplankton (<2 μm), nanophytoplankton (2–20 μm), and microphytoplankton (>20 μm) at stations in the Chesapeake Bay (CB), the Delaware Inland Bays (DIB) and the Delaware Bay (DB), in early spring 2005. At station CB microphytoplankton, including chain-forming diatoms were dominant, and the microzooplankton assemblage was mainly composed of the tintinnid Tintinnopsis beroidea. At station DIB, the dominant species were microphytoplanktonic dinoflagellates, while the microzooplankton community was mainly composed of copepod nauplii and the oligotrich ciliate Strombidium sp. At station DB, nanophytoplankton were dominant components, and Strombidium and Tintinnopsis beroidea were the co-dominant microzooplankton. The growth rate and grazing mortality rate were 0.13–3.43 and 0.09–1.92 d⁻¹ for the different size fractionated phytoplankton. The microzooplankton ingested 73, 171, and 49% of standing stocks, and 95, 70, and 48% of potential primary productivity for total phytoplankton at station CB, DIB, and DB respectively. The carbon flux for total phytoplankton consumed by microzooplankton was 1224.11, 100.76, and 85.85 μg C l⁻¹ d⁻¹ at station CB, DIB, and DB, respectively. According to the grazing mortality rate, carbon consumption rate and carbon flux turn over rates, microzooplankton in study area mostly preferred to graze on picophytoplankton, which was faster growing but was lowest biomass component of the phytoplankton. The faster grazing on Fast-Growing-Low-Biomass (FGLB) phenomenon in coastal regions is explained as a resource partitioning strategy. This quite likely argues that although microzooplankton grazes strongly on phytoplankton in these regions, these microzooplankton grazers are passive. Handling editor: K. Martens     

三峡水库香溪河库湾底泥中总氮、总磷含量的时空分布

2004年10月-2006年7月,对三峡水库香溪河库湾底泥中总氮(TN)、总磷(TP)含量的时空分布特征及其影响因素进行了分析.结果表明：香溪河库湾底泥中TN、TP含量均表现为“中间高,两头低”的空间分布规律,其中,TN含量最高值为1.08 mg·g^-1,出现在库湾中部区域,最低值为0.89 mg·g^-1,出现在河口附近区域;TP含量最高值为1.07 mg·g^-1,最低值为0.80 mg·g^-1,分别出现在库湾中部和库尾.TN含量按秋季、冬季、春季的顺序依次降低,从春季到夏季则大幅上升,夏季达最高值;TP含量的季节波动较小,以春季最高.研究区底泥中TN、TP含量的年际差异均达显著水平.香溪河库湾底泥中总氮、总磷含量的空间分布主要受水体中悬浮物质沉积率的影响,沉积率较高区域的TN、TP含量较高;TN含量的季节波动主要受上游来水量季节变化的影响,而TP含量 的季节变化主要源于点源污染.     

Sedimentation in Arctic Canada: Species composition and biomass of phytoplankton contributed to the marine sediments in Frobisher Bay

Summary Sedimentation of phytoplankton provides food and energy for zoobenthic communities. In this study the rates, species composition and biomass of phytoplankton input to Frobisher Bay sediments were examined during ice (late November to July) and open water (late July to October) periods from 1982 to 1985. The rates were higher on the sea bed than at 20 m. The minimum rate (3x10⁵ cells·m^-2·day^-1) of sedimentation occurred during the early part of the ice period. It increased as the ice thickened and reached a maximum of 2.8x10⁸ cells·m^-2·day^-1 after the phytoplankton bloom at the beginning of the open water period in the first two weeks of August. The sedimented phytoplankton was dominated by diatoms, with a great majority of pennate species during the spring (April to June) and centric forms during the summer (July to August). Green flagellates, dinoflagellates and chrysophytes occurred as a low percentage of the total population in all seasons. Other indicators (chlorophyll a and phaeopigments) showed highest biomass levels in the deepest traps. They were consistently low during the winter (December to March) and reached their maxima during the open-water period of summer. Their abundance was correlated with the seasonal cycle of the phytoplankton in the water column.     

Analysis of long-term variation in phytoplankton biovolume in the northern basin of Lake Biwa

The long-term variation in phytoplankton biovolume in the northern basin of Lake Biwa was analyzed using periodic phytoplankton census data from January 1979 to December 2009. Population densities obtained from census data were transformed into biovolumes, and phytoplankton species were categorized into three size fractions: net phytoplankton (≥4,000 μm³ cell^?1, ≥ca. 20 μm in diameter), large nanophytoplankton (100–4,000 μm³ cell^?1, ca. 6–20 μm in diameter), and small nanophytoplankton (<100 μm³ cell^?1, <ca. 6 μm in diameter). Although the annual total biovolume gradually decreased over time, the total biovolumes in winter and spring were found to increase. Furthermore, a decrease in the biovolume of net phytoplankton and an increase in that of small nanophytoplankton were observed. Because of succession in the phytoplankton community, the average cell volume of the phytoplankton community decreased from 269 μm³ cell^?1 in the 1980s to 56 μm³ cell^?1 in the 2000s. Lake warming accompanied with the intensification of thermal stratification and the augmentation of wind speed were observed at Lake Biwa over the study period. Serial analysis correcting for autocorrelation revealed that oligotrophication in the epilimnion, induced by lake warming and limitation of light available for phytoplankton growth by wind-induced water mixing, was a potential factor in the succession of the phytoplankton community.     

Abundance,growth and grazing loss rates of picophytoplankton in Barguzin Bay,Lake Baikal

The abundance, growth, and grazing loss rates of picophytoplankton were investigated in August 2002 in Barguzin Bay, Lake Baikal. Water samples for incubation were taken once at a near-shore station and twice at an offshore station. Contributions of picophytoplankton to total phytoplankton were high (56.9–83.9%) at the offshore station and low (5.8–6.8%) at the near-shore station. The picophytoplankton community in the offshore station comprised mainly phycoerythrin (PE)-rich cyanobacteria, with eukaryotic picophytoplankton being less abundant. In contrast, as well as PE-rich cyanobacteria and eukaryotic picophytoplankton, phycocyanin (PC)-rich cyanobacteria were found in the near-shore station. At the offshore station, growth and grazing loss rates on 25 August were 0.56 and 0.43 day⁻¹, respectively, and on 29 August, 0.69 and 0.83 day⁻¹, respectively. At the near-shore station, growth and grazing loss rates were 1.61 and 0.70 day⁻¹, respectively. These results show that there is a difference in the abundance, composition, and ecological role in the microbial food web of picophytoplankton between the near-shore and the offshore areas in Barguzin Bay.     

Picophytoplankton, nanophytoplankton, heterotrohpic bacteria and viruses in the Changjiang Estuary and adjacent coastal waters

Flow cytometry (FCM) was used to examine the abundances anddistributions of different picophytoplankton groups (i.e. Synechococcus,Prochlorococcus and picoeukaryotes), nanophytoplankton, heterotrophicbacteria and viruses were examined in the Changjiang Estuary,China and adjacent coastal waters during autumn 2004. Watertemperature and light availability were found to be criticalfactors for picophytoplankton growth. Positive correlationswere found between picophytoplankton, heterotrophic bacteriaand viruses, and a seaward-increasing trend in the V-I (thegroup yielding high green fluorescence according to FCM) populationwithin viruses was detected. The importance of nanophytoplanktonis progressively usurped by picophytoplankton with increasingdistance offshore. Picoeukaryotes are the most successful groupamong picophytoplankton in near-shore eutrophic waters, whereasProchlorococcus surpasses other groups within the pico- andnanophytoplankton community in offshore oligotrophic regionsof the East China Sea Shelf.