洞庭湖湖滩矮埂保水生态灭螺水域育珠性能的试验研究

在湖滩矮埂保水生态灭螺水域中,进行育珠性能试验研究的结果表明,本水域特别对三角帆蚌具有优良的育珠性能;在冬、春两季湖滩落水干枯期间,矮围能保水50cm以上,活螺和螺卵淹死率达100％。     

新安江水库(千岛湖)水质时空变化特征及保护策略

为探索新安江水库(千岛湖)水质的变化规律及其影响因素,利用2009-2010年的逐月水质监测数据,结合文献资料,对新安江水库水质时空变化进行了综合分析.结果表明:在时间分布上,透明度、总氮、总磷及叶绿素受水文季节变化过程、浮游生物生长及人类活动等的综合影响,具有明显的季节变化特征,特别是上游街口断面各指标季节差异显著.空间分布上,上游水质明显劣于下游水质,上游水域透明度低,氮、磷及叶绿素含量高,反映出外源供给和人类活动对新安江水库水质的决定性贡献,控制外源污染是新安江水库水质提升的关键.统计分析表明,新安江水库主要感官指标透明度主要受控于藻类生物量,而藻类生物量变化与氮、磷营养盐的含量关系密切.严格控制入库营养盐通量,控制浮游植物生物量的季节性异常增殖已成为解决新安江水库水环境问题的核心.另外,新安江水库经济鱼类赋存量与捕捞量对水质有一定影响,年度捕捞量与水体透明度具有反相关关系,不能排除鱼类密度过高导致的生态系统失调的可能.因此,要进一步开展渔业养殖的水质效应研究,加强渔业管理,确定科学合理养殖模式,保证新安江水库水质的改善.     

鄱阳湖浮游植物时空变化特征及其对极端洪枯事件的响应

鄱阳湖作为中国最大的淡水湖泊,其水生态健康状态始终是人们关注的热点。近些年,鄱阳湖极端洪旱灾害频发,浮游植物生长受极端洪旱的影响发生了明显变化。为分析浮游植物时空变化特征、探究环境因子对鄱阳湖浮游植物影响机制以及极端洪枯事件对浮游植物的影响,利用结构方程模型(SEM)构建浮游植物与环境因子的影响路径模型,定量分析环境因子对浮游植物的影响程度。结果表明,鄱阳湖浮游植物以蓝藻、绿藻为主且有明显的季节特征,在7月丰水期浮游植物密度达到最高;由结构方程模型(SEM)可知,影响浮游植物密度最关键的因子为物理因子(水温>pH>透明度>溶解氧),其次为营养物质(总氮>硝态氮>总磷>磷酸盐),浮游植物对高温、高营养和高pH较偏好。2020年极端洪水和2022年极端高温干旱,浮游植物密度主要受水温、溶解氧、透明度等物理因子的影响;在影响较小的营养物质中,主要的限制性因素分别为磷和氮。与正常年份相比,极端洪水年鄱阳湖受入湖来水及降雨的增多,湖区水量急剧增加,“稀释”作用超过水温和透明度对浮游植物生长的促进作用造成浮游植物密度和生物量有所下降;在营养物质中,磷成为主要限制性因素。而极端高温干旱年受入湖来水的减少及湖水的快速蒸发,“浓缩”作用超过水温和透明度对浮游植物生长的抑制作用造成浮游植物密度和生物量显著增加,同时,营养物质对浮游植物的作用更加凸显。研究结果表明极端洪枯事件导致鄱阳湖浮游植物变化明显,确定其对浮游植物的影响机制,可以为极端洪枯事件下浮游植物监测、管理提供一定的理论基础。     

四种浮游植物生物量计算方法的比较分析

浮游植物是水生生态系统中重要的初级生产者,其生物量是反映其现存量的关键指标.本文利用具有3个处理组的围隔实验中的浮游植物数据,对文献中常见的计算浮游植物种群生物量和群落生物量的4种方法:标准法、细分法、粗分法和资料法进行比较,并分析采用这4种不同方法得到的浮游植物生物量与叶绿素a浓度的相关性.结果表明:粗分法是计算浮游植物生物量的高效方法,能够保证准确度和节省时间;提高浮游植物生物量计算准确度不是影响浮游植物生物量与叶绿素a浓度相关性显著程度的关键.通过比较剔除稀有种(生物量不超过群落生物量5%的种类)前后浮游植物生物量的差异,发现忽略稀有种会导致种类均匀度较高的浮游植物群落生物量严重偏低,建议浮游植物生物量的计算不能一概忽略稀有种.     

砷污染治理背景下阳宗海浮游植物生物量的时空分布模式及驱动因子

在社会经济发展和流域开发持续的背景下,砷污染已成为我国部分水体面临的重要环境问题,目前对砷污染防控的生态效应与修复效果评价仍缺乏系统识别。湖泊生态系统中浮游植物是重要的生产者,砷等重金属污染可以直接影响浮游植物生长、物种演替和初级生产力水平,浮游植物已成为指示砷污染水平及其生态效应的敏感指标。本研究以长期受到砷污染胁迫并经历污染治理的阳宗海为研究对象,设置南、中、北3个调查位点,于2015年4月-2019年12月对浮游植物和水质因子开展季节调查和空间分析,通过识别浮游植物生物量的时空分布模式与驱动因子,评价了砷污染与治理下浮游植物生物量的变化机制和生态修复效果。调查结果显示,采样期间阳宗海浮游植物以蓝藻门为主,浮游植物的生物量范围为0.7~30.4 mg/L,平均生物量在2016年最低((3.0±1.8) mg/L)、在2017年最高((10.5±8.9) mg/L)。ANOVA分析结果显示,浮游植物生物量存在显著的季节差异而空间差异不明显。相关分析结果显示,阳宗海浮游植物生物量与砷浓度和透明度呈显著负相关,而与水体温度和pH呈显著正相关。多元线性回归分析进一步显示,砷和水温是驱动阳宗海浮游植物生物量变化的显著环境因子。由此可见,在重金属污染湖泊经过修复后,水体砷遗留物的毒性效应仍然对浮游植物生长产生了明显的抑制作用,表明了水体重金属污染物可能具有长期的沉积物释放作用与持久的生态毒理效应。     

淡水浮游植物计数与定量方法

显微镜计数法是淡水浮游植物计数最常用的经典方法,是浮游植物生物量测定的基本方法,也是衡量其他测定方法准确性的依据.随着科技的发展,可见分光光度法、荧光分光光度法、流式细胞显微镜计数法、库尔特计数法等新型细胞计数法相继问世.对各种方法的特点进行比较,结果表明:光密度法、流式摄像机计数法、流式细胞仪法、叶绿素a法等仅能够分析测定浮游植物生物量,而显微镜法是测量浮游植物粒径的经典方法,不仅可以测定浮游植物生物量,还可以进行浮游植物的种类及群落结构分析.以上这些方法都可以用于浮游植物的计数与定量,可以根据不同的需求来选择最佳的浮游植物计数方法,如分析方便性、样本处理速率、样本大小等.但显微镜计数法在淡水生态学中具有不可替代的作用.     

水体富营养化改善过程中浮游植物群落对非生物环境因子的响应:以武汉东湖为例

针对武汉东湖存在营养状态梯度的5个子湖（郭郑湖、汤菱湖、团湖、庙湖、水果湖）,结合"空间换时间"理论,研究湖泊富营养状况改善过程中浮游植物群落对环境因子的响应.全年调查期间,各子湖综合营养状态指数分布范围为45.4~76.8,浮游植物密度及生物量变化范围分别为2.03×10⁶~245×10⁶ cells/L和0.819~19.9 mg/L.冗余分析结果显示,浮游植物的物种分布与水温、总氮、透明度、总溶解性固体、氨氮呈显著相关.采用多元逐步回归分析构建浮游植物密度、生物量与环境因子之间的最优响应方程,结果显示,总氮、水温是影响浮游植物密度的主要因子;对于浮游植物生物量而言,总磷、总氮浓度降低能够降低浮游植物生物量.通过对富营养程度改善进程中浮游植物群落组成的动态变化进行分析,发现浮游植物密度及生物量显著下降,但物种组成及生物多样性并未发生明显转变.此外,浮游植物物种多样性与水体富营养水平梯度并不呈现简单的线性相关.因此,在对富营养化湖泊进行修复时,应制定短期修复与长期维护双重措施,同时应重视生物多样性的重建,进而达到理想的修复效果.     

三峡小江回水区透明度季节变化及其影响因子分析

三峡成库后其季节调蓄过程使该水域湖沼学特征具有独特性.根据三峡小江流域回水区段为期2年的定位跟踪观测,对透明度(SD)和主要环境指标的相互关系进行分析研究.研究期间,小江回水区透明度均值为170±7cm,各采样点透明度差异不明显且季节变化过程一致,自春末夏初开始降至最低水平,夏季汛期相对稳定,夏末入秋持续升高,冬季维持在较高状态,入春后下降.对透明度和主要环境指标的相关性分析发现,无机悬浮颗粒(PIM)是影响透明度的主要指标.透明度同PIM、Chl.a多元回归模型为:SD=(-89.389±8.101)·lg(PIM)+(-84.008±8.624)·lg(Chl.a)+(264.132±8.232).汛期低水位状态下(145-150m)小江回水区水动力条件趋于天然河道,河道输沙量增加使无机悬浮颗粒含量远高于藻类生物量而成为影响透明度的主要环境指标.在中水位(150-156m)和高水位(156m以上),虽然藻类进入非生长季节,但水位抬升和水体滞留时间的延长促使悬浮颗粒物大量沉淀,悬浮生长于表层水体的藻类成为影响透明度的主要环境指标,生物作用对透明度的影响明显.     

不同混养模式下中华鲟养殖池透明度变化及其影响因素

中华鲟与背角无齿蚌和鲢鳙混养的池水透明度(SD)对比试验表明,1#池(对照)、2#池(挂养背角无齿蚌)、3#池(混养鲢鳙)透明度平均值分别为11.92、16.45、17.45 cm,分别较试验本底值依次提高26.69%、56.67%、66.19%.2#、3#池的透明度显著大于1#池,最高可达1倍.3个池透明度与各水质指标关系的Panel Data模型分别为:SD1=-0.0072 TSS+0.8353 NH 4+-N-2.1711 TN+0.6195 TP-0.0405 COD+16.7815,SD2=0.0030 TSS+3.8864 NH 4+-N+0.1893 TN-12.4585 TP***-0.0104 COD+24.5306,SD3=0.0381 TSS*+3.7821 NH 4+-N+0.6003 TN-15.0444TP***-0.4078 COD**+34.2992(*、**、***分别表示显著、较显著、极显著相关).TP是影响中华鲟养殖池透明度的主要指标,NH 4+-N、TN、COD是影响透明度的间接指标,而TSS是影响透明度的直接指标.在悬浮物浓度较高、水体浑浊的中华鲟养殖池水体中,鲢鳙的放养对透明度的提高效果显著优于背角无齿蚌.     

用生态修复调控浮游植物种群局部控制富营养化——以贵州红枫湖水质生态修复工程为例

利用物理生态工程在水深10 m左右,水位变幅7 m左右的贵阳红枫湖/水库(正常水位时57.2 km2)右二湾富营养水体进行局部(围隔水体面积1.33 hm2)生态修复.对工程前后和内外水体浮游植物的群落结构、丰度、生物量等进行比较,结果表明,当植物浮岛覆盖率超过1/5～1/3时(可视为阈值),物理生态工程可以调控浮游植物种群结构和丰度,浮游植物优势种群由生态修复前的微囊藻属、角甲藻属及同期外环境的蓝藻门蓝纤维藻属转变为硅藻门的直链藻属.工程内与工程外比较,种属数减少了29.4%,特别是减少了蓝藻中可能释放藻毒素的微囊藻、鱼腥藻等属,蓝藻丰度和生物量分别减少了55.5%和57.9%;而硅藻的种属数则增多120.0%,且其丰度和生物量分别增加了56.4%和60.3%.从藻类总体统计资料看,工程内与工程外比较,藻类丰度减少53.6%,生物量减少39.1%,透明度提高了数十厘米以上,稳定在120～220 cm.当工程区外浮游植物优势种群是蓝藻,暴发蓝藻水华,且可释放藻毒素的种属有多次检出时,工程区内仍然以硅藻为优势种,未曾检测出可释放藻毒素的种属,从而在红枫湖局部水体实现了水质改善和富营养化控制.在目前高污染负荷下恢复浅水湖泊沉水植被时,本项目发展的可全年镶嵌式种植包括香根草、杞柳等高杆植物在内的多种水面植物的浮岛可作为防浪削浪、遏制蓝藻、改善水质、提高透明度的先锋性措施,以保障局部水面植被覆盖面积超过上述阈值,成为保护沉水植物生长、遏制暴发蓝藻水华的可操作途径.     

Analysis of patterns of vertical and temporal distribution of phytoplankton using multifactorial analysis: Acidic Lake Caviahue, Patagonia, Argentina

Most existing studies on the algal communities of acid lakes are based on environments that have been caused by anthropogenic disturbances. Such lakes have a different origin compared to the natural acidic lakes and could be expected to differ also in the mechanisms controlling phytoplankton and trophic status. Planktonic community in Lake Caviahue is somewhat diverse in spite of the low pH of the water. Algae have a distinctive vertical distribution: the values of phytoplankton biomass remain constant throughout the water column and at times were highest in the upper end of the hypolimnion, forming a maximum or a layer of chlorophyll a at depth. The goal of this work was to investigate the factors influencing the seasonal and vertical distribution of phytoplankton. The lake was sampled between the years 2004 and 2006. Physical, chemical and biological parameters at different depths throughout the water column were determined. The interrelationships between environmental variables at different sampling dates were analyzed using an integration of multivariate matrices, multiple factor analysis, to analyze any joint partnerships in the samples. We found that phytoplankton biomass is dominated by Keratococcus rhaphidioides. With regard to zooplankton, we found a single species of rotifers (Philodina sp.). The two arms of the lake and the depths have different behaviours showing differences in the arms' conductivity, dissolved oxygen and pH. The more superficial layers were characterized by high values of phytoplankton and zooplankton biomass, organic and inorganic carbon, dissolved oxygen and pH. The deeper layers showed high values of chlorophyll a, ammonium and phosphorus (dissolved and particulate). From the multivariate analysis the relationships of the each algal species with pH, as a possible indicator of the degree of “acidophilia”, could be extracted.     

Integrated measurements of acoustical and optical thin layers I: Vertical scales of association

This study combined measurements from multiple platforms with acoustic instruments on moorings and on a ship and optics on a profiler and an autonomous underwater vehicle (AUV) to examine the relationships between fluorescent, bioluminescent, and acoustically scattering layers in Monterey Bay during nighttime hours in July and August of 2006 and May of 2008. We identified thin bioluminescent layers that were strongly correlated with acoustic scattering at the same depth but were part of vertically broad acoustic features, suggesting layers of unique composition inside larger biomass features. These compositional thin layers nested inside larger biomass features may be a common ecosystem component and are likely to have significant ecological impacts but are extremely difficult to identify as most approaches capable of the vertical scales of measurement necessary for the identification of sub-meter scale patterns assess bulk properties rather than specific layer composition. Measurements of multiple types of thin layers showed that the depth offset between thin phytoplankton and zooplankton layers was highly variable with some layers found at the same depth but others found up to 16 m apart. The vertical offset between phytoplankton and zooplankton thin layers was strongly predicted by the fraction of the water column fluorescence contained within a thin phytoplankton layer. Thin zooplankton layers were only vertically associated with thin phytoplankton layers when the phytoplankton in a layer accounted for more than about 18–20% of the water column chlorophyll. Trophic interactions were likely occurring between phytoplankton and zooplankton thin layers but phytoplankton thin layers were exploited by zooplankton only when they represented a large fraction of the available phytoplankton, suggesting zooplankton have some knowledge of the available food over the entire water column. The horizontal extent of phytoplankton layers, discussed in the second paper in this series, is likely an important factor contributing to this selective exploitation by zooplankton. The pattern of vertical offset between phytoplankton and zooplankton layers was consistent between studies in different years and using different combinations of platforms, indicating the importance of the relationship between zooplankton layers and the fraction of phytoplankton within a layer at night within Monterey Bay. These results highlight the value of integrating measurements of various types of organisms to understand thin layers processes and the importance of assessing ecological interactions in plankton thin layers within the context of the properties of the entire water column, like the animals themselves do.     

三峡水库小江回水区水华暴发期浮游植物群落结构及其与环境因子的关系

三峡水库蓄水以来,支流水华频发,尤以小江情况最为严重,给三峡库区的生态安全带来较大隐患。为探究支流水华暴发特征和主控因素,于2014-2021年小江水华暴发期间在小江高阳江段进行浮游植物及环境因子调查,并使用单因素方差分析、聚类分析、百分比相似性分析以及基于距离的线性模型等方法,对小江水华暴发期间浮游植物和环境因子在不同年份不同水层间的差异以及二者的关系进行研究。结果表明:小江水华暴发期内,浮游植物的种类数在43~70种之间,其中2015年蓝藻种类数明显减少,2018年以后硅藻种类数明显减少;采样期间浮游植物平均细胞密度在0.66×10⁶~61.28×10⁶ cells/L之间,同期表层细胞密度明显高于中层和底层;各层水体间水华微囊藻、铜绿微囊藻、不定微囊藻等10种藻的密度存在明显差异,是主要差异种;显著影响表层、中层和底层浮游植物群落结构变动的环境因子是水位的日平均变幅;水位的日平均变幅与藻类优势种拟合关系显示,当日水位下降幅度在0.5 m以上时,浮游植物平均密度会呈指数级减少。研究结果可为三峡库区支流水华的防控提供数据支持。     

Coastal thin layer dynamics: Consequences to biology and optics

Thin layers are fine-scale structures with high concentrations of organisms or particles occurring over very small vertical scales (a few meters or less), but with large horizontal scales, often extending for many kilometers. Because of their small vertical scales, thin layers are traditionally under sampled, but when proper measurement techniques are used, thin layers have been found to be ubiquitous in stratified oceans. A multi-investigator, interdisciplinary study of thin layers was sponsored by the US Office of Naval Research under a research initiative termed: Layered Organization in the Coastal Ocean (LOCO). The goal of this program was to understand the properties of coastal thin layers and the interacting physical, chemical, biological and optical processes responsible for their formation, maintenance and dissipation. As part of this program, fine-scale vertical profiles (cm resolution) of biological, physical and chemical properties were made hourly over periods spanning 1–3 weeks during three summers in Monterey Bay, California USA. The vertical profiles were made using arrays of moored autonomous profilers. In total, these profilers made ~2000 individual vertical profiles and provided a unique view of phytoplankton thin layer spatial-temporal dynamics. The autonomous profiler data were supplemented with high-resolution ship-based profiling and discrete water sampling for identifications of organisms.Persistent phytoplankton thin layers were observed during each year in Monterey Bay; however, each year had very different biological and physical dynamics. During 2002, thin layers were dominated by the non-motile and potentially toxic diatom genus Pseudo-nitzschia; during 2005, thin layers were dominated by the highly motile dinoflagellate species Akashiwo sanguinea; and during 2006, a more complex phytoplankton assemblage was present, but thin layers of the toxic dinoflagellate species Alexandrium catenella frequently occurred. The variability in the vertical location of thin layers in 2002 was primarily controlled by physics, while behavior, e.g. diurnal vertical migration patterns and daytime near-surface aggregations, primarily controlled the location of thin layers in 2005 and 2006. In 2002, phytoplankton thin layers were present in the water column 87% of the time, in 2005, 56% of the time and in 2006, 21% of the time. The median integrated chlorophyll concentration within the thin layers was found to be approximately 47% of the total water column chlorophyll in 2002, 41% in 2005 and 33% in 2006. Additional results in this study describe the mechanisms driving the spatial-temporal dynamics of these phytoplankton thin layers with special emphasis on diel patterns and the specific relationships that thin layers have to biological and physical processes and water column optics.     

Thin layers and species-specific characterization of the phytoplankton community in Monterey Bay,California, USA

During the summers of 2005 and 2006, experiments designed to understand the properties of densely concentrated, thin layers of plankton and the processes governing their dynamics were conducted in Monterey Bay, California, USA. Our goal was to elucidate the role that species-specific properties of phytoplankton play in thin layer dynamics. Using adaptive sampling, we collected water samples from inside and outside bio-optical features of the water column. Characterization of the phytoplankton was compiled from live and preserved samples, and analyzed within a framework of physical, optical, chemical and acoustical data. In both years, Monterey Bay was home to an extraordinarily diverse assemblage of phytoplankton and other protists. Bioluminescent dinoflagellates, and Harmful Algal Bloom (HAB) taxa were common. In 2005, community assemblages were widespread, thus advection of water through the experimental mooring array did not result in floristic changes. In 2006 phytoplankton were very patchy in horizontal distribution, and advection of water through the array was at times accompanied by dramatic shifts in community composition. Individual taxa often exhibited disparate patterns of vertical distribution, with some found throughout the water column, whereas others were restricted to narrow depth intervals. Thin layers were observed in both years. In 2005, the dinoflagellate Akashiwo sanguinea formed intense thin layers near the pycnocline at night, and migrated to near surface waters at dawn. In 2006, layer composition was more complex, and related to the water mass present at the time of sampling. Optically detected thin layers of phytoplankton can be studied from the perspective of the impact their high biomass has on both ecological processes, and ocean optics. But thin layers can also be studied from the species-specific perspective of each organism, its role within the thin layer habitat, and the impact that life within a thin layer has on its life history and ecology. Several low-abundance taxa appeared to be restricted to narrow depth intervals in the water column, and constitute species-specific thin layers with the potential to have a large ecological impact even if their biomass is too low to dominate an optically defined thin layer. Concentration into thin layers may also facilitate obligatory relationships between taxa, such as the hypothesized interrelationships between cryptomonads, Myrionecta rubra, and Dinophysis spp., all of which were observed in this system. Complexity of vertical structure in Monterey Bay rivals that already demonstrated in topographically constrained, stratified systems, and presents challenges to our theoretical framework of phytoplankton ecology.     

Salsvatn,a lake with old sea water

Salsvatn is a 464 m deep lake laying 16 m above sea level in North Trøndelag, Norway. The lake was isolated from the sea some 3,000 years ago. It is assumed that salt-water in the deepest 50 m of the lake is the remain of sea water being trapped in the lake at this time. The concentration of cloride in the salt-water layer corresponds to a salinity of 29‰ in ordinary sea water. Hydrography of the lake and changes in some components of the salt water compared with ordinary sea water are discussed. Comparison is made with changes in the stagnant layers of the Black Sea and Lake Rørholtjorden. The latest is another lake with old sea-water at its bottom. Surface sediment samples have been collected from the freshwater and salt-water layers in Lake Rørholtfjorden and from the salt-water layer of Lake Salsvatn. Some chemical components of the sediments and interstitial water have been analysed and discussed.     

以鲢、鳙养殖为主的长江中下游武山湖浮游植物群落结构特征

武山湖是紧邻长江的通江型富营养化湖泊,是国家级湿地公园.为切实了解该湖在以鲢、鳙养殖为主的情况下浮游植物结构特征,于2017年9月-2018年8月对其浮游植物群落结构特征及水质开展了监测.监测结果表明武山湖水质全年处于轻度富营养到重度富营养水平之间;12次共采集浮游植物7门100种（属）,浮游植物优势种共有23种,其中蓝藻门有9种,绿藻门有8种,硅藻门和隐藻门各有3种.夏季和秋季蓝藻门优势种最多且优势度高,冬季和春季绿藻门和硅藻门优势种多且优势度高.武山湖浮游植物每月优势度最大的种类主要有蓝藻门微囊藻和细小平裂藻、绿藻门小球藻以及硅藻门小环藻.浮游植物生物量峰值出现在6月,达34.77 mg/L;丰度峰值出现在7月,达341.46×10⁶ cells/L.冗余分析（RDA）和线性相关分析均表明浮游植物丰度和生物量与总磷、温度和pH均呈显著正相关,且蓝藻门生物量和丰度以及优势属与总磷和温度均呈显著正相关.研究结果表明武山湖浮游植物丰度和生物量在夏季均很高,发生蓝藻水华的风险较大.相对于氮,磷是更重要的限制浮游植物生长的营养元素.     

湖北长湖富营养化状况及时空变化(2012-2013年)

为评估长湖水体富营养化程度,2012-2013年分4个季度对全湖区20个采样点的物理、化学和生物要素进行监测,在评价水质现状的基础上采用综合营养状况指数法和浮游植物细胞丰度指数法综合评价水体营养状况,并应用典型相关分析(CCA)方法揭示水体富营养化状况与湖泊理化要素之间的典型相关性.结果显示:4个季节长湖全湖区的水质均处于地表水IV类~劣V类水标准;综合营养状态指数值在49.54~82.55之间,浮游植物细胞丰度在2.88×106~61.73×106cells/L之间,均显示其处于富营养化状态;长湖富营养化状况的分布呈现一定的时空差异性;CCA分析显示,长湖理化要素变量可解释68.6%的水体富营养化状况变量的变异,影响其富营养化状况的主要理化因素有水体总磷、总氮、溶解氧、亚硝态氮、硝态氮浓度,水深和沉积物总磷、总氮含量.长湖水体富营养化主要是由于外源的磷污染,其次是氮污染,富营养化最严重的夏、秋季浮游植物的生长主要受氮营养限制,而冬、春季则部分受磷营养限制,部分属于过渡类型.因此,建议大力削减围网/围栏养殖量,同时考虑结合水生植物栽种等生态工程建设措施以降低长湖水体发生严重富营养化的风险,并进一步改善长湖的水质现状.     

阳宗海砷污染背景下浮游植物的时空分布特征及其驱动因子解析

人类活动导致的重金属污染是湖泊水体面临的主要环境压力之一.云南高原湖泊阳宗海于2008年暴发了砷污染事件且水体砷浓度目前仍然超过生活饮用水卫生标准,严重影响了水安全和生态系统健康.本研究于2015年4月-2016年2月每两月对阳宗海南、中、北部湖区进行采样调查及分析,共鉴定出浮游植物7门44属68种,绿藻门种数最多.蓝藻门占绝对优势,其中伪鱼腥藻（Pseudoanabaena sp.）、浮丝藻（Planktothrix sp.）、束丝藻（Aphanizomenon sp.）为全年的优势种,这与已有调查显示的阳宗海砷污染后浮游植物群落中蓝藻占优的基本特征一致.方差分析结果表明浮游植物生物量在时间尺度上呈现显著的变化特征,最大值出现在8月（14.06 mg/L）,最小值出现在12月（1.23 mg/L）,而空间差异不显著.Pearson相关分析显示,浮游植物总生物量与水温、pH呈显著正相关.而与砷、透明度、锰、钠、钾和总磷浓度呈显著负相关,冗余分析结果表明,水温、砷、钙、锰、钾共同解释了阳宗海浮游植物群落结构变化的57.18%.方差分解的结果进一步表明,水温、钙离子和砷三者作用共同解释了浮游植物群落结构变化的32.05%,其中水温和钙离子分别独立解释了群落变化的12.45%和8.28%,水体砷浓度仅独立解释了2.33%,但与水温共同作用解释了9.46%.因此,我们推测水温的季节性波动导致了湖泊水体热力分层的明显变化,其中水体混合作用的增强可能会促进底泥释放过程并增加表层水体的砷浓度,进而影响了浮游植物群落的季节性变化.研究结果有利于评价重金属污染对湖泊的长期生态效应,并为砷污染湖泊的环境修复提供重要的科学依据.