Multiple subsurface phytoplankton blooms occurring simultaneously in the Skagerrak

The distribution and characteristics of phytoplankton in theSkagerrak in August–September 2000 were analysed in orderto evaluate the importance of subsurface phytoplankton peaksto water column ecology and primary production. In areas affectedby outflow from the Baltic, enhanced chlorophyll concentrationswere found in the warm surface waters (i.e. upper 10–20m). However, for the central Skagerrak, the major part (50–80%)of the chlorophyll in the water column was found below the warmsurface waters. The highest chlorophyll concentrations (up to>18 µg l^-1) in the study area were also found belowthe warm surface waters and up to 95% of total water columnprimary production was recorded below the warm surface waterlayer. Measurements of variable fluorescence (F_v/F_m) indicatedthe greatest potential capacity for electron flow in photosystemII in phytoplankton was located below the warm surface waters.Spectrophotometrically determined pigment ratios suggest thatthe enhanced capacity for photosynthesis in the deeper watersmay be related to greater nutrient availability here than insurface waters. Subsurface chlorophyll distributions seen inrelation to the different water masses identified in the area,as well as community analysis of the phytoplankton present inthe subsurface peaks, indicate the presence of at least threedistinct subsurface phytoplankton blooms in the Skagerrak duringthe study period. Local oxygen saturation maxima recorded immediatelyabove the subsurface peaks provide in situ evidence that thesepeaks are photosynthetically active. This suggests that newproduction is taking place in these peaks, although quantificationof this production is hampered due to a lack of informationconcerning the initial conditions in and lifetime of the subsurfacepeaks. The subsurface phytoplankton peaks were, generally, foundimmediately above an oxygen minimum that covered the entirestudy area. In the relatively cold deep Atlantic water foundbelow the oxygen minimum layer, no or very little chlorophyllwas recorded and oxygen concentrations increased. Thus, it isargued that the respiration of the organic material producedin the upper part of the water column during late summer mayprimarily occur in the intermediate layers of the water column.     

Photobleaching Response of Different Sources of Chromophoric Dissolved Organic Matter Exposed to Natural Solar Radiation Using Absorption and Excitation–Emission Matrix Spectra

CDOM biogeochemical cycle is driven by several physical and biological processes such as river input, biogeneration and photobleaching that act as primary sinks and sources of CDOM. Watershed-derived allochthonous (WDA) and phytoplankton-derived autochthonous (PDA) CDOM were exposed to 9 days of natural solar radiation to assess the photobleaching response of different CDOM sources, using absorption and fluorescence (excitation-emission matrix) spectroscopy. Our results showed a marked decrease in total dissolved nitrogen (TDN) concentration under natural sunlight exposure for both WDA and PDA CDOM, indicating photoproduction of ammonium from TDN. In contrast, photobleaching caused a marked increase in total dissolved phosphorus (TDP) concentration for both WDA and PDA CDOM. Thus TDN∶TDP ratios decreased significantly both for WDA and PDA CDOM, which partially explained the seasonal dynamic of TDN∶TDP ratio in Lake Taihu. Photobleaching rate of CDOM absorption a(254), was 0.032 m/MJ for WDA CDOM and 0.051 m/MJ for PDA CDOM from days 0–9, indicating that phototransformations were initially more rapid for the newly produced CDOM from phytoplankton than for the river CDOM. Extrapolation of these values to the field indicated that 3.9%–5.1% CDOM at the water surface was photobleached and mineralized every day in summer in Lake Taihu. Photobleaching caused the increase of spectral slope, spectral slope ratio and molecular size, indicating the CDOM mean molecular weight decrease which was favorable to further microbial degradation of mineralization. Three fluorescent components were validated in parallel factor analysis models calculated separately for WDA and PDA CDOM. Our study suggests that the humic-like fluorescence materials could be rapidly and easily photobleached for WDA and PDA CDOM, but the protein-like fluorescence materials was not photobleached and even increased from the transformation of the humic-like fluorescence substance to the protein-like fluorescence substance. Photobleaching was an important driver of CDOM and nutrients biogeochemistry in lake water.     

Physical-Biological Coupling in the Western South China Sea: The Response of Phytoplankton Community to a Mesoscale Cyclonic Eddy

It is widely recognized that the mesoscale eddies play an important part in the biogeochemical cycle in ocean ecosystem, especially in the oligotrophic tropical zones. So here a heterogeneous cyclonic eddy in its flourishing stage was detected using remote sensing and in situ biogeochemical observation in the western South China Sea (SCS) in early September, 2007. The high-performance liquid chromatography method was used to identify the photosynthetic pigments. And the CHEMical TAXonomy (CHEMTAX) was applied to calculate the contribution of nine phytoplankton groups to the total chlorophyll a (TChl a) biomass. The deep chlorophyll a maximum layer (DCML) was raised to form a dome structure in the eddy center while there was no distinct enhancement for TChl a biomass. The integrated TChl a concentration in the upper 100 m water column was also constant from the eddy center to the surrounding water outside the eddy. However the TChl a biomass in the surface layer (at 5 m) in the eddy center was promoted 2.6-fold compared to the biomass outside the eddy (p < 0.001). Thus, the slight enhancement of TChl a biomass of euphotic zone integration within the eddy was mainly from the phytoplankton in the upper mixed zone rather than the DCML. The phytoplankton community was primarily contributed by diatoms, prasinophytes, and Synechococcus at the DCML within the eddy, while less was contributed by haptophytes_8 and Prochlorococcus. The TChl a biomass for most of the phytoplankton groups increased at the surface layer in the eddy center under the effect of nutrient pumping. The doming isopycnal within the eddy supplied nutrients gently into the upper mixing layer, and there was remarkable enhancement in phytoplankton biomass at the surface layer with 10.5% TChl a biomass of water column in eddy center and 3.7% at reference stations. So the slight increasing in the water column integrated phytoplankton biomass might be attributed to the stimulated phytoplankton biomass at the surface layer.     

Phytoplankton sinking rates in the Rhine region of freshwater influence

According to Stokes’ law, colony formation in phytoplanktonwould lead to enhanced sinking rates and higher sedimentationlosses if colonies had the same densities as the phytoplanktoncells they contain. In the Dutch coastal zone of the North Sea,algae settling out of the water column are subject to zoobenthosgrazing or to physical mixing into the sediment and, therefore,the formation of colonies by common diatom species and the prymnesiophytePhaeocystis globosa seems paradoxical: it would increase theprobability that sedimentation becomes a significant loss factor.However, sinking rate measurements in the Rhine region of freshwaterinfluence (ROFI) using SetCol settling columns did not reveala straightforward relationship between phytoplankton sizes (<10to >1000 µm) and sinking rates (–0.4 to >2.2m day^-1) of 24 autotrophic phytoplankton species and groups.In fact, under nutrient-replete conditions, the sinking ratesof the diatoms Chaetoceros radicans, Rhizosolenia shrubsoleiand Rhizosolenia stolterfothii decreased with size. The sinkingrates of large colonies of the prymnesiophyte P. globosa werealso negatively correlated with their size and positive buoyancywas observed. Chlorophyll a sinking rates exceeded 1 m day^-1periodically, which is sufficient to cause significant surfacelayer loss rates over 0.2 day^-1. Under stratified conditions,both chlorophyll a concentrations and sinking rates in the bottomlayer were significantly higher (+49% and +16%, respectively)than in the surface layer. These observations are discussedin relation to Stokes’ law, together with a critical analysisof the SetCol technique. It is concluded that: (i) SetCol givesadequate results when incubations are performed at or near insitu irradiance and temperature; (ii) sinking rates are predominantlydetermined by cell or colony density rather than their size;(iii) periodic sedimentation is an important species-specificloss process for phytoplankton in the Dutch coastal zone. Itis speculated that for diatoms with low sinking rates, autolysisis an important loss factor.     

Measurement of in situ growth rates of phytoplankton under conditions of simulated turbulence

In situ measurement of the growth rates of planktonic populationscan be improved by using dialysis chambers (‘cage cultures’)to avoid shifts in the chemical environment during incubation.Vertical mixing and small-scale turbulence affect the growthof planktonic populations, there fore natural mixing conditionsshould be simulated as closely as possible during the incubation.A new device is described here which combines the advantagesof a dialysis chamber with a programmable vertical mixing regime.Realistic phytoplankton growth rates can thus be measured insitu under con ditions of vertical mixing and small-scale turbulence.The chamber made of transparent, UV-transmitting acrylic glasswas fitted at both ends with permeable polycarbonate membranes.It was moved vertically through the water column by a pocket-sizedlift and rotated simultaneously on its central axis. The methodwas applied to two typos of experiments on growth and lossesof phytoplankton in the River Severn, UK. The first one comparedchanges in biovolume of phytoplankton in a water parcel flowingdownstream (6% h^–1 decline) with those in a simultaneouslyincubated dialysis chamber moved between water surface and riverbottom (7% h^–1 increase). The difference equates to algallosses prevented in the chamber but suffered along the river(mainly sedimentation and grazing of benthic filter feeders).Loss rate of diatoms was three times higher than those of chlorophytes.In another experiment growth of phytoplankton from the mainstream and lateral dead zone was compared under different mixingconditions. Algae from the main stream grew faster than fromthe dead zone. Only cryptophytes preferred calm conditions,all the other algal groups grew faster in chambers moved throughthe water column than in stationary ones. Further possible applicationsin both standing and flowing waters are discussed.     

Temporal and vertical variation of chlorophyll a concentration, phytoplankton photosynthetic activity and light attenuation in Lake Kinneret: possibilities and limitations for simulation by remote sensing

The relationship between chlorophyll a (Chl a) and primary productivity(PP) in the uppermost water layer and the water column-based(0–15 m) integral values of those variables were examinedusing measurements taken in Lake Kinneret (Israel) from 1990to 2003. In 81% of all Chl a profiles examined, the distributionwas fairly uniform within the entire 0–15 m water column,and 12.3% of instances showed a prominent subsurface maximum,when the lake phytoplankton was dominated by the dinoflagellatePeridinium gatunense. Chl a can be reliably estimated by remotesensing techniques in the productive and turbid water of LakeKinneret, since Chl a concentration at surface layers can beextrapolated to the entire water column. Light vertical attenuationcoefficient average for wavelengths from 400 to 700 nm, K_d,ranged from 0.203 to 1.954 m^–1 and showed high degreeof temporal variation. The maximal rate of photosynthetic efficiency,P_B^opt [average 3.16 (±1.50)], ranged from 0.25 to 8.85mg C m^–3 h^–1 mg Chl a^–1. Using measured dataof Chl a, P_B^opt, and light as an input, a simple depth-integratedPP model allowed plausible simulation of PP. However, a lackof correlation between photosynthetic activity and temperature(or other variable with remotely sensed potential) renders theuse of models that require input of photosynthetic efficiencyto calculate integrated PP of little value in the case of productiveand turbid Lake Kinneret.     

Response of Sargasso Sea phytoplankton biomass, growth rates and primary production to seasonally varying physical forcing

The response of phytoplankton biomass, growth rates and primaryproduction to seasonally varying physical forcing was studiedat a station southeast of Bermuda over an 18 month period. Phytoplanktongrowth rates and primary production were measured using thepigment-labeling method, and phytoplankton biomass was calculatedfrom these measurements. Phytoplankton carbon biomass variedsystematically over the year. Highest values were observed duringthe winter and spring. Seasonal variations of chlorophyll (Chi)a in the surface layer could primarily be attributed to variationsin phytoplankton biomass and secondarily to photoacclimation.During the summer period, average values of carbon (C)/Chl ratios(g C g^–1 Chi) ranged from 160 at the surface to 33 atthe 1.6% light level, changes attributed to photoacclimationof the phytoplankton, consistent with the observation that phytoplanktonbiomass did not vary as a function of depth. Phytoplankton growthrates in the surface layer did not vary systematically overthe year, ranging from 0.15 to 0.45 day^–1, in spite ofseasonally varying concentrations of nitrate. Growth rates variedas a function of depth from average values of 0.3 day^–1in the surface layer to <0.1 day¹ at the 1.6% light level.Thus, the primary response of the phytoplankton community tonutrient enrichment during the winter period was an increasein phytoplankton biomass rather than an increase in growth rates.A simple nutrient-phyto-plankton-zooplankton model was usedto explore this phenomenon. The model demonstrated that theobserved response of the phytoplankton to nutrient enrichmentis only possible when phytoplankton growth is not severely limitedby nutrients.     

Dominance of microflagellates over diatoms in the Antarctic areas of deep vertical mixing and krill concentrations

Phytoplankton data obtained during six summer Polish expeditionsto the Antarctic Peninsula area, are compared with concurrentlyrecorded data on water column stabilities and krill abundance.The results show that flagellates (1.5–20 µm) arenumerically dominant over diatoms in the areas of deep verticalmixing and/or extensive krill concentrations. Of 102 stationsdominated by flagellates, 85 (83.3%) are located in a well mixedwater column (>100 m) and correspond to a mean krill densityof 15–346 t Nm^–2. In the same areas, estimated flagellatecarbon biomass exceeds diatom carbon. On the other hand, ofthe 40 stations dominated by diatoms, 36 (90%) are located inareas of increased water column stability (upper mixed layerof 10–50 m) and correspond to a low mean krill biomassof 0.34–4.6 t Nm^–2. Positive correlations of flagellateto diatom (F:D) cell number ratios with the depth of the uppermixed layer suggest light limitation of diatom growth and anincreased sinking rate of diatoms relative to flagellates inthe areas of deep vertical mixing. The relationship of the F:Dratio with krill abundance suggests that krill prefer feedingon diatoms and are less efficient in grazing particles of thesize of microflagellates (<20 µm). Flagellates exceeddiatoms in an unstable water column when the phytoplankton populationsare low; both algal groups increase in numbers with growingstability. The results provide field evidence that deep verticalmixing and krill grazing create conditions for the dominanceof flagellates over diatoms. Both factors acting together arelikely to suppress diatom blooms in the Antarctic.     

Cell surface elemental composition of Microcystis aeruginosa: high-Si and low-Si subpopulations within the water column of a eutrophic lake

Energy-dispersive X-ray microanalysis (10 kV microprobe) wascarried out to determine the surface elemental composition ofsingle cells of Microcystis aeruginosa within mixed phytoplanktonpreparations, sampled at different depths (0–8 m) withina stratified eutrophic lake. Mean elemental concentrations (mmolkg^–1 dry weight) throughout the sampled water column were:magnesium, 125; silicon (Si), 1864; phosphorus, 341; sulphur,122; chlorine, 88; potassium, 282; calcium, 63. Although somesignificant differences in elemental composition occurred withdepth, the underlying pattern was one of relative uniformitywithin the top 8 m of the water column. At each depth, the frequencydistribution of Si was bimodal, indicating two distinct subpopulationsof cells with cell surface Si concentrations ranging from 0to 1000 mmol kg^–1 (overall mean 112, low-Si cells) andfrom 1000 to 6800 mmol kg^–1 (overall mean 3649, high-Sicells). The two subpopulations occurred mixed together withinindividual colonies, and both included dividing and non-dividingcells. Both cell types had a wide range of sizes, but high-Sicells reached a higher maximum size in both dividing (diametergreater by 0.90 µm) and non-dividing (difference of 0.44µm) cells. This difference in size is consistent withSi being present as a surface layer (up to 0.2–0.4 µmin thickness) in high-Si cells. Support for the presence ofa surface layer of Si [with aluminium (Al)] is also providedby correlation analysis (Si and Al are significantly negativelycorrelated with other cell elements), principal component analysis(Si and Al occur as a distinct subgroup) and lower mean concentrationsof elements (other than Al) in high-Si cells (due to reducedX-ray contribution from the cell interior). The proportion ofhigh-Si cells in the water column was locally high in the 2m depth sample, and had an overall value of 40.5% for the wholedata set. The biological significance of high- and low-Si cellsis not known.     

Space-time variability of carbon standing stocks and fixation rates in the Gulf of Maine, along the GNATS transect between Portland, ME, USA, and Yarmouth, Nova Scotia, Canada

The Gulf of Maine North Atlantic Time Series has been run since1998 and is the longest transect time series in the Gulf ofMaine (GoM), USA. Here we use this coastal time series to documentthe space–time variability of hydrography, nutrients,phytoplankton standing stocks and carbon fixation in the GoM,in response to several years of extreme river discharge. Wehypothesize that, during wet years, fresh water input cappedthe surface euphotic layer, impeding the upward diffusion ofnutrients, thus lowering the phytoplankton biomass and carbonfixation rates. Regional algorithms were derived to estimateparticulate organic carbon and carbon fixation. The Howard–Yoderalgorithm was implemented to predict integral primary productionusing satellite ocean color data. Calcification was significantlycorrelated to primary production, thus allowing regional, satellite-derivedcalcification estimates. Total GoM and Georges Bank phytoplanktonphotosynthesis was 38.12 Tg C year^–1 and total calcificationwas 0.55 Tg C year^–1, yielding an overall ratio of calcificationto photosynthesis of 1.44%. Carbon fixation in GoM coastal water(<60 m bottom depth), GoM deep water (>60 m) and GeorgesBank waters (<60 m) averaged 33, 56 and 11% of the totalprimary production of the combined GoM and Georges Bank studyarea, respectively, and 22, 67 and 11% of the total calcificationof the study area, respectively.     

Phytoplankton dynamics within the subsurface chlorophyll maximum of Lake Michigan

The Lake Michigan deep chlorophyll maximum during July 1977was a broad band of phytoplankton –15 m thick rather thanthe thin layers observed in smaller lakes. The maximum concentrationof chlorophyll was typically four times surface values. ¹⁴Cuptake incubations showed that the deep plankton layer was aviable component of the pelagic ecosystem accounting for upto 60% of primary production on an areal (m²) basis. The LakeMichigan chlorophyll maximum was composed primarily of largediatoms, filaxnentous green algae, and flagellates. Althoughlarge scale physical processes such as seiches had some effecton the chlorophyll maximum, the basic integrity of the layerwas maintained by biological processes. In particular, epilinmeticnutrient depletion was apparently a major factor affecting thevertical distribution of phytoplankton. Application of a diffusionmodel to the chemical and chlorophyll data indicated that nutrientuptake and primary production by phytoplankton were more importantin determining chemical and chlorophyll vertical profiles thandiffusivity. ¹Contribution No. 389 from the Great Lakes Research Division,University of Michigan.     

Occurrence of dinoflagellate Alexandrium tamarense, a causative organism of paralytic shellfish poisoning in Chinhae Bay, Korea

A paralytic shellfish poisoning (PSP) incident caused by consumptionof the mussel Mytilus edulis occurred for the first time inKorea in April 1986. Weekly water samplings were carried Outduring the period from 7 March to 21 April 1989 in Chinhae Bay,Korea, in order to identify the causative organism. The temperaturecharacteristics of the water column indicated three differenthydrological regimes: well mixed (up to 7 March), weakly stratified(17–31 March) and stratified (7–21 April). Toxicityof the phytoplankton was detected during the weakly stratifiedperiod, but only in the 10–50 p.m phytoplankton size fraction.This study presents the occurrence of the toxigenic dinoflagellateAlexandrium tamarense, which is a causative organism of PSP,in Korean coastal waters. Its biomass varied at different depthsin the water column, ranging from 200 to 8000 cells 1^–1in the water column. The weekly fluctuation of A.tamarense toxicitywas similar to that of mussel toxicity. ¹ Present address: Department of Biology, College of NaturalSciences, Hanyang University, Seoul 133-791, Korea     

Optically active components and light attenuation in an offshore station of Harima Sound, eastern Seto Inland Sea, Japan

In the eastern Seto Inland Sea, Japan, phytoplankton abundance in the surface water has gradually declined, whereas Secchi depth has risen in recent years, particularly in offshore areas. Therefore, it may be hypothesized that phytoplankton dominate light attenuation in the offshore area, and that other constituents are less important. To test this hypothesis, we examined the roles of seawater, colored dissolved organic matter (CDOM), non-algal particles (tripton), and phytoplankton in the light attenuation at an offshore station of Harima Sound in the eastern Sea. The magnitude of light attenuation was then determined from the attenuation coefficient of photosynthetically available radiation (PAR) through the water column (K _d). During a 13-month period, K _d ranged from 0.179 to 0.507 m^?1, with a mean of 0.262 m^?1. The mean relative contributions of seawater (15%) and CDOM (13%) to K _d were small, while the most dominant K _d constituent was tripton (45%). The mean contribution of phytoplankton to K _d (27%) was consequently less than that of tripton. However, 75% of the temporal variability in K _d was attributed to phytoplankton, measured as chlorophyll a. Our results emphasize that the main component of light attenuation does not always govern the temporal variation of light attenuation in coastal regions.     

Possible biogeochemical response to the passage of Hurricane Fabian observed by satellites

Physical and biogeochemical changes induced by the HurricaneFabian in the Northwest Atlantic in early September 2003 wereobserved using composite satellite images. After the passageof the hurricane, the mean sea surface temperature (SST) alongthe track decreased on average by about 1.3°C with maximumdecrease of 10°C. At the same time, the mean Chl a concentrationincreased by about 42%. Entrainment of cold, nutrient-rich watersby vertical mixing induced by the hurricane seems to have enhancedthe phytoplankton production. Asymmetric distribution of changesin SST and Chl a (strong intensity on the right side of thestorm track) was observed from the satellite data. The storm-inducednitrate increase estimated from the satellite SST, using a localrelationship between nitrate and temperature measurements wasabout 40% on average along the track of the storm. A numericalmodel study and climatological nutrient profile showed an increasein mixed-layer depth of 26 m and nitrate increase of about 0.2µmol L^–1 after the storm passage. In addition toaltering the physicochemical conditions of the water column,physical forcing by the hurricane also changed the taxonomiccomposition of phytoplankton. It is inferred that the dominanceof diatoms after the storm is a result of the increase in nutrientconcentration within the mixed layer due to the wind forcingof the storm.     

Vertical distribution of virus-like particles (VLP) and viruses infecting Micromonas pusilla during late summer in the southeastern Skagerrak, North Atlantic

Vertical profiles were made at one offshore station and onecoastal station, on 4-5 September 1996, in the south-easternSkagerrak. The surface water of the two stations differed significantlywith respect to both temperature and salinity, as the outerstation (A) was situated in high-saline water originating fromthe North Sea, while the low-saline surface water at the innerstation (B) was influenced by the Baltic current. Virus-likeparticle (VLP) abundance was 5 x 10⁹–25 x 10⁹1^–1H in the 0-50 m water column. Maximal VLP values were foundin the surface water, although a lower number was detected inthe low-saline surface water (0 m depth) at station B. Virusesinfective to Micromonas pusilla were estimated to     

Seasonal and interannual variability of size-fractionated phytoplankton biomass and community structure at station Kerfix, off the Kerguelen Islands, Antarctica

Time series of phytoplankton biomass and taxonomic compositionhave been obtained for the 3 years 1992, 1993 and 1994 in thenorthern part of the Southern Ocean (station Kerfix, 5040'S,6825;E) Autotrophic biomass was low throughout the year (<0.2mg m^–3 except during a short period in summer when a maximumof 1.2 mg chlorophyll (Chl) a m– was reached. During winter,the integrated biomass was low (<10 mg m^–2) and associatedwith deeply mixed water, whereas the high summer biomass (>20mg m^–2) was associated with increased water column stability.During summer blooms, the >10 µ;m size fraction contributed60% to total integrated biomass. Large autotrophic dinoflagellates,mainly Prorocentrum spp., were associated with the summer phytoplankton maxima and accounted for >80% of the total autotrophcarbon biomass. In November and December, the presence of thelarge heterotrophic dinoflagellates Protoperidinium spp. andGyro dinium spp. contributed a high proportion of total carbonbiomass. During winter, the <10 µm size fraction contributed80% of total Chi a biomass with domination of the picoplanktonsize fraction. The natural assemblage included mainly nakedflagellates such as species of the Prasinophyceae, Cryptophyceaeand Prymnesiophyceae. During spring, picocyanobacteria occurredin sub-surface water with a maximum abundance in September of106 cells 1^–1     

Predicting the spatial dominance of phytoplankton in a light limited and incompletely mixed eutrophic water column using the PROTECH model

1. A phytoplankton community model [Phytoplankton RespOnses To Environmental CHange (PROTECH)] was used to examine the effect of a wide range of varied light intensities and mixed depths upon simulated phytoplankton populations. Two different column lengths of the simulated water body were examined (the upper 5 m and the whole 14.5 m water column) for each scenario.
2. The hypotheses tested were that: (i) under low light intensity and/or deep mixing the simulated community will be dominated by a phytoplankter with a low critical light intensity; (ii) at high light intensity and shallow mixing the simulated community will be dominated by small, fast-growing phytoplankters; (iii) under all conditions, except deep mixing, the largest proportion of phytoplankton biomass will be found near the surface.
3. It was found under most conditions that, although there was a bloom in the upper column (dominated by algae such as Chlorella , Ceratium or Rhodomonas ), the largest phytoplankton biomass in the water column was located 9 m below the surface and consisted of solely Asterionella . This bloom was missed by the 5-m samples. Thus, using the whole column sample lengths, hypothesis (i) was not rejected but hypotheses (ii) and (iii) were refuted.
4. The inclusion of specific movement characteristics of phytoplankton in the model allowed the possibility of the dominance of multiple spaces within the water column and should be included in any model-based investigation of this topic. Further, the results from the model suggest that a reduced depth of mixing creates greater environmental heterogeneity, allowing more species to persist.     

2006年秋季东海陆架浮游植物群集

根据2006年11月19日—12月24日在东海陆架海域（24.0°—32.0°N,120.0°—127.0 °E）进行的综合采样调查,对调查海域浮游植物的群集特征进行了研究.本次调查共发现浮游植物4门64属145种（包括未定名种）,其中硅藻是该调查海区浮游植物的主要功能群,其次为甲藻.主要的优势种为菱形海线藻、圆海链藻、丹麦细柱藻、斯氏几内亚藻、尖刺伪菱形藻和铁氏束毛藻等.浮游植物细胞丰度为0.09～5.11 cells·ml^-1,平均值为4.92 cells·ml^-1,秋季东海陆架浮游植物细胞丰度的平面分布主要由浮游硅藻刻画,其高值出现在调查区的北、东部离岸海域,细胞丰度大于30 cells·ml^-1.浮游植物及硅藻和甲藻的细胞丰度垂直变化趋势基本上都是随着水深增加,丰度逐渐减小.各个断面细胞丰度密集区主要集中在表层,个别站位的中层和底层也出现浮游植物密集区.调查区浮游植物的多样性指数平均值为2.80,其高值位于调查区东北和东南部,物种均匀度指数平均值为0.81,其高值位于调查区中部,生物多样性的分布与细胞丰度的分布一致.从Pearson相关性指数来看,亚硝酸盐、溶解态有机氮(DON)和温度显著影响调查区浮游植物的生长.     

Primary production, light and vertical mixing in Potter Cove, a shallow bay in the maritime Antarctic

Phytoplankton photosynthesis was measured during spring-summer 1991-1992 in the inner and outer part of the shallow Potter Cove, King George Island. Strong winds characterise this area. Wind-induced turbulent mixing was quantified by means of the root-mean square expected vertical displacement depth of cells in the water column, Z_t. The light attenuation coefficient was used as a measure of the influence of the large amount of terrigenous particles usually present in the water column; 1% light penetration ranged between 30 and 9 m, and between 30 and 15 m for the inner and outer cove, respectively. Obvious differences between photosynthetic capacity [P*_max; averages 2.6 and 0.6 µg C (µg chlorophyll-a)^-1 h^-1] and photosynthetic efficiency {!*; 0.073 and 0.0018 µg C (µg chlorophyll-a)^-1 h^-1 [(µmol m^-2 s^-1)^-1]} values were obtained for both sites during low mixing conditions (Z_t from 10 to 20 m), while no differences were found for high mixing situations (Z_t>20 m). This suggests different photoacclimation of phytoplankton responses, induced by modifications of the light field, which in turn are controlled by physical forcing. Our results suggest that although in experimental work P*_max can be high, wind-induced mixing and low irradiance will prevent profuse phytoplankton development in the area.     

Development and fate of Eutreptiella gymnastica bloom in nutrient-enriched enclosures in the coastal Baltic Sea

Response of the phytoplankton community to bottom-up (nutrients,organic carbon source) and top-down (fish) manipulations, bothsingly and together, were studied daily during a 3 week periodin July 1993 by using eight 50 m³ mesocosms in the coastal northernBaltic Sea. Nutrient additions (once per week) invoked a seriesof blooms of Eutreptiella gymnastica Throndsen (Euglenophyceae)(up to 13 x 10³ cells ml^–1) which formed the major part(60–90%) of the total autotrophic biomass. After rapiddepletion of nutrients (2–3 days) from the surface layer(0–6 m) downwards migration and a subsequent peak of E.gymnasticain the lower part of the water columns (6–12 m) followed.Settled material collected from the bottom of the enclosurescontained a considerable amount of E.gymnastica cells and restingcysts. Nevertheless, sinking loss rates of E.gymnastica wereestimated to be less than 1% day^–1 of the suspended cellnumbers. The fate of E.gymnastica blooms was estimated to begrazing through mesozooplankton. However, provided the nutrientsare plentiful in the water column, the growth potential of E.gymnasticaappears to exceed the ambient grazing pressure. If the nutrientsbecome depleted, it seems to be effectively controlled by mesozooplanktongrazing, which is probably limiting the likelihood of massiveE.gymnastica blooms in the coastal Baltic Sea. Our study suggeststhat E.gymnastica appears to be a fast-growing fugitive (bloom)species with flexible behavioural (vertical migration) and lifehistory (cyst formation) adaptations which is able to exertdominant role and direct trophic relations similar to otherbloom species adapted for decaying turbulence and high nutrientenvironments.