2016—2017年夏季舟山近岸海域富营养化程度与浮游植物多样性          下载免费PDF全文

金敬林  蔡丽萍  余健涛 《海洋开发与管理》2020,37(1):51-55

文章根据2016-2017年夏季的调查资料,对2016-2017年夏季舟山近岸海域富营养化状态及浮游植物进行分析。结果表明:2016-2017年夏季舟山近岸海域富营养化程度较高,且由近岸至外海递减;浮游植物群落主要由硅藻和甲藻组成,其密度、多样性指数均由近岸至外海递增;受其他因素影响,富营养化程度与浮游植物多样性关系的规律性不显著。  相似文献   

钦州湾海洋环境的富营养化水平评价及其对浮游植物叶绿素a的影响          下载免费PDF全文

康建华  林毅力  王雨  蓝文陆 《海洋开发与管理》2020,37(11):67-74

文章通过钦州湾现场调查资料，分别利用单因子污染指数法和富营养化指数法对湾内水质的污染状况和富营养化水平进行评价，并分析讨论不同的富营养化水平条件下浮游植物叶绿素a的响应。结果显示，钦州湾的污染状况和富营养化程度从湾顶至湾外呈现由重至轻的梯度变化，并出现两个“极端区域”：茅尾海化学需氧量（COD）和营养盐的污染指数劣于三类海水水质标准并重度富营养化；外湾污染指数符合一类海水水质标准并贫营养化。分析表明，茅尾海的重度富营养化是由河流输入、相对封闭的地形以及过度的牡蛎养殖造成，而外湾的贫营养化则主要归因于较少的水产养殖和陆源污水排放以及大量的浮游植物对磷酸盐的消耗。叶绿素a在这两个区域均呈现低值，茅尾海内主要是由于贝类滤食大粒径浮游植物和真光层深度下降引起，而外湾则是氮磷比（N/P）失衡，浮游植物生长受磷限制导致。另外，核电站温排水有可能是导致叶绿素a较高的原因。减少茅尾海内的养殖规模，种植红树林，集中污水于外湾排放，加强温排水口的水质监控是保证钦州湾海洋生态环境可持续发展的手段。  相似文献   

珠江口典型海岛周边水域浮游植物分布特征及其影响因素*     

苏芯莹  钟瑜  李尧  谭美婷  黄亚东  刘珊  徐向荣  宋星宇 《热带海洋学报》2020,39(5):30-42

旅游业为海岛带来可观经济效益的同时, 人类活动也导致水体生态环境恶化, 如水体富营养化加剧、赤潮频发等。文章通过对珠江口东南部典型海岛——庙湾岛和外伶仃岛周边水域丰水期和枯水期现场环境数据与浮游植物分布特征的对比研究, 分析珠江径流等自然因素以及人类活动对河口天然海岛周边水体生态的潜在影响。枯水期外伶仃岛和庙湾岛周边水域海水分别镜检鉴定出76种和74种浮游植物, 两个海岛浮游植物平均细胞密度分别为2.62×10⁴个·L^-1和2.08×10⁴个·L^-1; 丰水期则分别鉴定出38种和47种浮游植物, 平均细胞密度分别为52.91×10⁴个·L^-1和170.57× 10⁴个·L^-1。在外伶仃岛和庙湾岛, 丰水期中肋骨条藻(Skeletonema coatatum)均为绝对优势种, 而枯水期两个岛的最主要优势种分别为窄隙角毛藻(Chaetoceros affinis)和新月筒柱藻(Cylindrotheca closterium), 物种多样性指数均明显高于丰水期。两个海岛微型浮游植物相对于其他两个粒级常占据优势地位, 但在丰水期, 小型浮游植物贡献明显上升, 其中外伶仃岛相对于枯水期由16.32%升至26.75%, 庙湾岛则由12.12%升高至24.78%。两个海岛在丰水期和枯水期均仅检出聚球藻(Synechococcus, Syn)和真核微微型藻类(eukaryotic, Euk)两大微微型浮游植物类群, 两者细胞密度分别为~10⁷个·L^-1及~10⁸个·L^-1量级。与环境因子的对比分析表明, 两个海岛浮游植物的区域分布与季节变化受多种因素影响, 其季节性差异主要受径流影响强度、影响范围以及相应的盐度、营养盐等环境因素的季节变化所调控。丰水期岛屿屏蔽效应对浮游植物丰度的区域分布特征有显著影响, 无论小型浮游植物还是微微型浮游植物均发现存在迎流面出现丰度高值分布的现象, 但对群落结构的分布影响不明显; 在枯水期, 水体环境很可能主要受人类活动与水体垂直混合扰动的综合影响, 总体上浮游植物分布的区域差异较小。  相似文献   

城市湖泊春季绿藻水华特征及其影响因素——以宁波月湖为例     

周卢茜  裘钱玲琳  唐剑锋  徐耀阳  潘军标  王小德 《湖泊科学》2019,31(4):1023-1034

城市湖泊富营养化问题日趋严峻，以往对水华的研究多集中于大型自然淡水湖库，而对小型城市浅水湖泊的水华动态相对较少.以宁波月湖为研究对象，探讨水华暴发期间浮游植物变化特征及与影响因子之间的关系，以期判别影响城市湖泊水华的主控因子.月湖水华期间营养盐水平处于中富营养至极端富营养之间，此次共检出浮游植物8门61属，藻种组成以绿藻门（51.79%）和硅藻门（21.43%）为主，各点位浮游植物生长主要受水温、光照驱动，经历了隐藻门→硅藻门→绿藻门→蓝藻门的演替.水华种为雷氏衣藻（Chlamydomonas reinhardtii），总藻密度最高达到1.55×10⁸ cells/L，水华暴发后各点位衣藻属比例升高（最高达到81.10%），群落结构呈现单一化特征.通过Pearson相关性分析和RDA分析发现衣藻属生长与水温、pH、总磷浓度均呈显著正相关，春季气温回升、天气持续晴好，城市浅水湖泊高营养盐负荷、水体流动性差等特点为带鞭毛的衣藻属提供了适宜的生存条件，在环境条件均适宜的情况下拥有最大生长潜力的衣藻属在营养盐、光照等竞争中生长速率明显优于其他藻种，从而发生绿藻水华.  相似文献   

Isolation of 12 microsatellite markers following a pyrosequencing procedure and cross-priming in two invasive cryptic species, Alexandrium catenella (group IV) and A. tamarense (group III) (Dinophyceae)     

Martin Laporte  Zhaojun Shao  Patrick Berrebi  Mohamed Laabir  Eric Abadie  Nicolas Faivre  Fabien Rieuvilleneuve  Estelle Masseret 《Marine pollution bulletin》2014

Alexandrium catenella (group IV) and Alexandrium tamarense (group III) (Dinophyceae) are two cryptic invasive phytoplankton species belonging to the A. tamarense species complex. Their worldwide spread is favored by the human activities, transportation and climate change. In order to describe their diversity in the Mediterranean Sea and understand their settlements and maintenances in this area, new microsatellite markers were developed based on Thau lagoon (France) samples of A. catenella and A. tamarense strains. In this study twelve new microsatellite markers are proposed. Five of these microsatellite markers show amplifications on A. tamarense and ten on A. catenella. Three of these 12 microsatellite markers allowed amplifications on both cryptic species. Finally, the haplotypic diversity ranged from 0.000 to 0.791 and 0.000 to 0.942 for A. catenella and A. tamarense respectively.  相似文献   

近海浮游植物水华动力学和生物气候学研究综述     

宋洪军  季如宝  王宗灵 《地球科学进展》2011,26(3):257-265

浮游植物水华作为近海重要的生物过程,其动态变化对生态系统内的能童传递、生产力水平和各生源要素的循环等均有重要影响.随着气候变化对生态系统影响研究的深入,浮游植物水华生物气候学研究已成为当前生物海洋学研究的热点.综述了浮游植物水华的研究历史、研究方法及其发生发展的动力学机制,重点评述了气候变化对浮游植物水华动态的影响及国...  相似文献   

Characterisation of water masses and phytoplankton nutrient limitation in the East Australian Current separation zone during spring 2008     

C.S. Hassler  J.R. DjajadikartaM.A. Doblin  J.D. EverettP.A. Thompson 《Deep Sea Research Part II: Topical Studies in Oceanography》2011,58(5):664-677

This study focuses on the comparison of oceanic and coastal cold-core eddies with inner-shelf and East Australian Current (EAC) waters at the time of the spring bloom (October 2008). The surface water was biologically characterised by the phytoplankton biomass, composition, photo-physiology, carbon fixation and by nutrient-enrichment experiments. Marked differences in phytoplankton biomass and composition were observed. Contrasted biomarker composition suggests that biomarkers could be used to track water masses in this area. Divinyl chlorophyll a, a biomarker for tropical Prochlorophytes, was found only in the EAC. Zeaxanthin a biomarker for Cyanophytes, was found only within the oceanic eddy and in the EAC, whereas chlorophyll b (Chlorophytes) was only present in the coastal eddy and at the front between the inner-shelf and EAC waters.This study showed that cold-core eddies can affect phytoplankton, biomass, biodiversity and productivity. Inside the oceanic eddy, greater phytoplankton biomass and a more complex phytoplankton community were observed relative to adjacent water masses (including the EAC). In fact, phytoplankton communities inside the oceanic eddy more closely resembled the community observed in the inner-shelf waters. At a light level close to half-saturation, phytoplankton carbon fixation (gC d⁻¹) in the oceanic eddy was 13-times greater than at the frontal zone between the eddy and the EAC and 3-times greater than in the inner-shelf water. Nutrient-enrichment experiments demonstrated that nitrogen was the major macronutrient limiting phytoplankton growth in water masses associated with the oceanic eddy. Although the effective quantum yield values demonstrate healthy phytoplankton communities, the phytoplankton community bloomed and shifted in response to nitrogen enrichments inside the oceanic eddy and in the frontal zone between this eddy and the EAC. An effect of Si enrichment was only observed at the frontal zone between the eddy and the EAC. No response to nutrient enrichment was observed in the inner-shelf water where ambient NO_x, Si and PO₄ concentrations were up to 14, 4 and 3-times greater than in the EAC and oceanic eddy. Although results from the nutrient-enrichment experiments suggest that nutrients can affect biomass and the composition of the phytoplankton community, the comparison of all sites sampled showed no direct relationship between phytoplankton biomass, nutrients and the depth of the mixed layer. This is probably due to the different timeframe between the rapidly changing physical and chemical oceanography in the separation zone of the EAC.  相似文献   

Phytoplankton composition and biomass across the southern Indian Ocean   总被引：2，自引：0，他引：2  

Louise Schlüter  Peter HenriksenTorkel Gissel Nielsen  Hans H. Jakobsen 《Deep Sea Research Part I: Oceanographic Research Papers》2011,58(5):546-556

Phytoplankton composition and biomass was investigated across the southern Indian Ocean. Phytoplankton composition was determined from pigment analysis with subsequent calculations of group contributions to total chlorophyll a (Chl a) using CHEMTAX and, in addition, by examination in the microscope. The different plankton communities detected reflected the different water masses along a transect from Cape Town, South Africa, to Broome, Australia. The first station was influenced by the Agulhas Current with a very deep mixed surface layer. Based on pigment analysis this station was dominated by haptophytes, pelagophytes, cyanobacteria, and prasinophytes. Sub-Antarctic waters of the Southern Ocean were encountered at the next station, where new nutrients were intruded to the surface layer and the total Chl a concentration reached high concentrations of 1.7 ??g Chl a L⁻¹ with increased proportions of diatoms and dinoflagellates. The third station was also influenced by Southern Ocean waters, but located in a transition area on the boundary to subtropical water. Prochlorophytes appeared in the samples and Chl a was low, i.e., 0.3 ??g L⁻¹ in the surface with prevalence of haptophytes, pelagophytes, and cyanobacteria. The next two stations were located in the subtropical gyre with little mixing and general oligotrophic conditions where prochlorophytes, haptophytes and pelagophytes dominated. The last two stations were located in tropical waters influenced by down-welling of the Leeuwin Current and particularly prochlorophytes dominated at these two stations, but also pelagophytes, haptophytes and cyanobacteria were abundant. Haptophytes Type 6 (sensuZapata et al., 2004), most likely Emiliania huxleyi, and pelagophytes were the dominating eucaryotes in the southern Indian Ocean. Prochlorophytes dominated in the subtrophic and oligotrophic eastern Indian Ocean where Chl a was low, i.e., 0.043-0.086 ??g total Chl a L⁻¹ in the surface, and up to 0.4 ??g Chl a L⁻¹ at deep Chl a maximum. From the pigment analyses it was found that the dinoflagellates of unknown trophy enumerated in the microscope at the oligotrophic stations were possibly heterotrophic or mixotrophic. Presence of zeaxanthin containing heterotrophic bacteria may have increased the abundance of cyanobacteria determined by CHEMTAX.  相似文献   

Phytoplankton dynamics and cyanobacterial dominance in Murchison Bay of Lake Victoria (Uganda) in relation to environmental conditions   总被引：2，自引：0，他引：2  

Sigrid Haande  Thomas RohrlackRonald P. Semyalo  Pål BrettumBente Edvardsen  Anne Lyche-SolheimKai Sørensen  Petter Larsson 《Limnologica》2011,41(1):20-29

Murchison Bay is a shallow embayment in the north-western part of Lake Victoria, strongly influenced by urban pollution from the Ugandan capital Kampala. Two stations, representing the semi-enclosed innermost part of the bay and the wider outer part of the bay, were sampled in the period from April 2003 to March 2004, in order to assess the phytoplankton community and the nutrient status in the bay. Murchison Bay was highly eutrophic with average concentrations (n=25) of total phosphorous >90 μg L⁻¹ and total nitrogen >1100 μg L⁻¹ in the inner part of the bay. The phytoplankton community was dominated by a variety of cyanobacterial species and diatoms. Cyanobacteria were dominant in the whole bay, whereas diatoms were more abundant in the outer part of the bay. Moreover, the proportion of N-fixing species like Anabaena sp. was higher in the outer part of the bay, whereas species like Microcystis sp. were more abundant in the inner part of the bay. The phytoplankton community, especially in the outer part of the bay, may be influenced by light limitation. Low NO₃-N concentrations in the bay may also indicate a possible N-limitation, thus favouring growth of N-fixing cyanobacteria. The open bay is, however, a complex system, and additional environmental factors and loss processes most likely affect the phytoplankton community.  相似文献   

Air-sea CO₂ exchange of beach and near-coastal waters of the Chukchi Sea near Barrow, Alaska     

Hiroki Ikawa  Walter C. Oechel 《Continental Shelf Research》2011,31(13):1357-1364

Partial pressure of CO₂ in equilibrium with sample water (pCO₂) for the coastal water in the Chukchi Sea was continuously observed in summer, 2008. Average daily CO₂ flux calculated from the pCO₂ and gas transfer coefficients ranged from −0.144 to −0.0701 g C m⁻² day⁻¹ depending on which gas transfer coefficient was used. The pCO₂ before the landfast ice sheets melted appeared to be highly biologically controlled based on the following information: (1) the diurnal pattern of pCO₂ was strongly correlated with Photosynthetic Photon Flux Density (PPFD); (2) high chlorophyll density was observed during periods of peak uptake; and (3) the day-to-day variation in the pCO₂ strongly correlated with the presence or absence of near-shore ice sheets. The lowest pCO₂ of 35 ppm together with the highest PPFD of 1362 μmol E m⁻² s⁻¹ were observed in the afternoon on June 28 in the presence of sea ice. The very low pCO₂ observed in late June was likely caused by high photosynthetic rates related to high phytoplankton densities typically observed from spring to early summer near the ice edge, and by water low in salinity and CO₂ released by melting sea ice early in the season.  相似文献