胶州湾水温和营养盐硅限制初级生产力的时空变化

根据作者近年来对胶州湾水域的主要研究结果,分析和探讨了营养盐硅和水温对浮游植物生长的变化和其集群结构的改变影响,研究了胶州湾初级生产力的年变化过程是如何受到营养盐硅和水温的限制和提高,其时间阶段和空间区域又如何划分,营养盐硅和水温如何控制不同阶段和不同区域的初级生产力。同时,揭示了营养盐硅或水温在时间和空间的尺度上如何控制浮游植物生长的变化过程,而且在时空的变化中,2种因子营养盐硅和水温在时间和空间的尺度上又如何有顺序的控制,产生出各种类型的生产力。研究结果展示了在初级生产力的时间和空间的变化过程中,营养盐硅和水温控制初级生产力的不同时间阶段,尤其用增殖能力展示了水温对浮游植物生长的控制时间阶段;营养盐硅控制初级生产力的不同空间区域。从而阐明了营养盐硅和水温控制初级生产力的变化过程。从陆地到海洋界面的硅输送量决定了初级生产力的时间变化过程;硅的生物地球化学过程决定了初级生产力的空间变化过程。因而,营养盐硅和水温是浮游植物生长的“发动机”,营养盐硅是主要的,而水温是次要的。     

地球生态系统的营养盐硅补充机制

通过海洋生态系统的结构和功能以及海洋生态系统对大气生态系统和陆地生态系统的影响,根据营养盐硅对浮游植物生长的影响过程和浮游植物的生理特征以及其集群结构的改变特点的研究结果,综合分析了硅的生物地球化学过程,探讨了人类对生态环境的影响和生态环境变化对地球生态系统的影响。提出了地球生态系统的营养盐硅的补充机制:近岸的洪水、大气的沙尘暴和海底的沉积物向缺硅的水体输入大量的硅,即由陆地、大气、海底3种途径将硅输入海水水体中,满足浮游植物的生长的需要,保持海洋中浮游植物生长的动态平衡,促进海洋生态系统的可持续发展。     

胶州湾浮游植物研究Ⅱ环境因子对浮游植物群落结构变化的影响

该文依据 1995年 3月～ 1996年 1月间浮游植物的调查资料 ,并结合同期水温和营养盐的资料变化 ,分析不同环境因素对浮游植物群落结构的影响。结果表明 :水温的变化对浮游植物的种类组成和数量变化都有一定影响 ,秋季和冬季优势种交替明显 ;营养盐对浮游植物群落结构的变化影响明显。根据胶州湾营养盐结构的改变状况 ,并结合历史资料对比发现 ,胶州湾网采浮游植物的物种数和细胞数量呈下降趋势 ,优势种类趋单一化 ;但初级生产力并未下降 ,可能与微型浮游植物所占份额增大相关。     

浮游植物生长上行效应的研究进展

归纳了海洋浮游植物生长营养盐限制的研究方法,综述了国内外关于海水中氮、磷、硅、铁等营养元素限制浮游植物生长的研究结果。在氮、磷营养元素限制时,海水中上述两个元素的浓度不仅限制了浮游植物的生长,而且还改变了浮游植物的种群结构,随着营养盐浓度的降低,浮游植物从小型向微型、微微型转变;而硅的缺乏,使浮游植物由硅藻向非硅藻转变;在大洋海域,铁的限制,甚至还影响到浮游植物对常量营养盐的吸收。铁施肥虽然促进了浮游植物的生长,降低了大气中CO2的浓度,缓解了温室效应,但同时也伴随着有毒藻类的生长以及DM S气体增加等带来的诸多问题。     

胶州湾营养盐限制作用空间差异和长期变化的数值研究

以胶州湾为研究区域,建立箱式生态动力学模型,模拟得到胶州湾浮游植物生长受营养盐限制情况的季节变化;通过数值实验分析了胶州湾营养盐限制的区域差异,并进一步比较了1960、1980年代及本世纪初营养盐限制情况的区别。结果表明,胶州湾内的营养盐限制作用有显著的季节变化。春季由于浮游植物旺发消耗大量营养盐,使得湾内营养盐限制春末最强;夏季是河流丰水季,营养盐补充充足,湾内营养盐限制最弱。从不同区域来看,养殖区全年表现为硅限制;河口区和湾口区夏季为磷限制,其他季节为硅限制。营养盐限制作用湾口区最强,养殖区次之,河口区最弱。受此影响,浮游植物生物量河口区最高,湾口区最低。从长期变化来看,1960年代,胶州湾内的营养盐限制作用以氮限制为主,1980年代呈硅和磷交替限制,逐渐演变到本世纪初的以硅限制为主,而且由于营养盐限制作用的逐渐增强,浮游植物生物量也呈现不断下降的趋势。     

大亚湾浮游植物粒级结构对温排水和营养盐输入的响应*

大亚湾核电站温排水对其邻近海域的生态效应日益突出。文章结合现场调查和室内模拟实验, 研究了夏季和冬季大亚湾海域沿温排水温度梯度的浮游植物粒径结构特征, 探讨了营养物质的输入可能对其产生的影响, 以期深入了解浮游植物对升温以及富营养化作用的响应机制。结果表明, 适温条件对浮游植物的生长起促进作用, 在极高温(36.0℃)环境下则产生抑制作用, 在排水口邻近高温区夏季和冬季浮游植物叶绿素a含量均呈较低分布。交互模拟实验发现不同季节浮游植物对于温度和营养盐的敏感性存在差异, 夏季营养盐对浮游植物生长的促进作用比温度明显, 冬季温度的作用则更为显著。现场观测和模拟实验均显示, 水温升高和营养盐加富均可造成小粒级浮游植物 (<20μm)所占比例的增加; 因此, 升温和营养盐输入均可能导致浮游植物粒级结构呈小型化趋势, 并对食物网能量流动与物质循环、生态系统的结构稳定性以及海洋渔业的产量造成潜在影响。     

大亚湾浮游植物粒级结构对温排水和营养盐输入的响应

大亚湾核电站温排水对其邻近海域的生态效应日益突出。文章结合现场调查和室内模拟实验,研究了夏季和冬季大亚湾海域沿温排水温度梯度的浮游植物粒径结构特征,探讨了营养物质的输入可能对其产生的影响,以期深入了解浮游植物对升温以及富营养化作用的响应机制。结果表明,适温条件对浮游植物的生长起促进作用,在极高温(36.0℃)环境下则产生抑制作用,在排水口邻近高温区夏季和冬季浮游植物叶绿素a含量均呈较低分布。交互模拟实验发现不同季节浮游植物对于温度和营养盐的敏感性存在差异,夏季营养盐对浮游植物生长的促进作用比温度明显,冬季温度的作用则更为显著。现场观测和模拟实验均显示,水温升高和营养盐加富均可造成小粒级浮游植物(20μm)所占比例的增加;因此,升温和营养盐输入均可能导致浮游植物粒级结构呈小型化趋势,并对食物网能量流动与物质循环、生态系统的结构稳定性以及海洋渔业的产量造成潜在影响。     

大鹏澳水域秋季浮游植物优势种的演替及其与春季的比较

根据2002年11月在亚大湾大鹏澳进行的连续30d(每日采样一次)观测资料，运用主成分分析和多元回归分析相结合方法，分析大鹏澳非养殖区中各浮游植物优势种之间的关系及影响其生长与演替的主要理化因子．建立秋季浮游植物优势种演替模型，并与春季的大鹏澳现场调查建立的浮游植物优势种演替模型进行比较，分析生境变化(降雨)对浮游植物优势种演替过程的影响。结果表明，春，秋季浮游植物优势种发生不同的演替过程。春季浮游植物对资源的竞争较为激烈，大量降雨引起海水中营养盐浓度升高，促进并维持中肋骨条藻(Skeletonema costatum)高密度生长，待营养盐被大量消耗后，中肋骨条藻数量下降，减轻了对柔弱菱形藻(Nitzschia delicatissima)的生长压力而使其成为优势种；而秋季水温较低，浮游植物细胞数量较春季大为减少，中肋骨条藻和柔弱菱形藻对资源的竞争较为缓和，使外界环境变化成为影响优势种变化的主要原因；降雨期间虽然营养盐增加，但环境变化使浮游植物的生长受到限制，雨后柔弱菱形藻数量不能恢复，水体中高营养盐浓度促使中肋骨条藻出现生长峰值。     

桑沟湾养殖海域营养盐和沉积物-水界面扩散通量研究

利用2006年4,7,11月和2007年1月4个航次对桑沟湾养殖海域的观测资料,分析了该海域营养盐分布、结构特征、主要控制过程以及沉积物-水界面扩散通量,结果表明,该海域的营养盐分布具有明显的季节变化,海水中NO3-,NO2-,PO43-,DOP,TDP和SiO32-浓度皆是秋季最高,而NH4+,DON,TDN浓度则为夏季最高;各种营养盐的最低值除DON外都出现在春季。春季湾内外海水交换不畅,再加上大型藻类海带等生长旺盛期的消耗,使营养盐浓度处于较低水平,在夏秋两季丰水期沿岸河流注入对该海域营养盐的影响较大,冬季无机营养盐浓度分布主要受沿岸流的影响。磷的结构变化较大,其中DOP百分含量在夏季最高,达到81%。从春季到秋季海水中TDN的结构变化从以DON为主转变成以DIN为主。硅和氮的原子比值全年变化不大,硅和氮和氮和磷原子比值春夏两季的高于秋冬季的。分析营养盐化学计量限制标准和浮游植物生长的最低阈值结果表明,磷是春夏两季桑沟湾浮游植物生长的限制性因素;春季硅浓度低于浮游植物生长的最低阀值,也是一个潜在的限制因素。计算结果显示桑沟湾沉积物释放的NH4+,SiO32-和PO43-对初级生产力的贡献较小,与其他浅海环境相比,桑沟湾沉积物-水界面的营养盐通量处于较低或中等水平。     

围隔生态系内不同粒级浮游植物群落变化研究

通过现场围隔实验,模拟赤潮发生过程,研究了种群不同生长阶段中不同粒级浮游植物种群的变化情况。结果表明,添加营养盐能有效促进浮游植物的生长,东海原甲藻围隔（M1）和自然水体围隔（M2）中浮游植物分别于第7天和第4天出现生长高峰,叶绿素a最大值分别为112．79mg／m和235．60mg/m。微型浮游植物与微微型浮游植物存在竞争,微型对微微型生长的抑制作用：M2〉M1。在营养盐丰富时,硅藻的增殖速率比东海原甲藻快,达到高峰期时间短,消亡也快。硅的减少促进硅藻水华的消亡。     

大亚湾夏季浮游植物群落结构及对淡澳河输入的响应特征*

浮游植物是水生生态系统的基础生产者, 其群落结构直接影响到生态系统的健康和安全。河流输入是人类活动影响大亚湾水体环境最重要的途径之一, 淡水输入改变了水体温度、盐度、浊度和营养盐等环境因子, 对浮游植物群落结构产生影响。文章调查研究了2015年河流输入最强的夏季丰水期大亚湾的水体环境因子和浮游植物群落结构, 分析了在较强河流输入影响下浮游植物群落结构的动态变化及其对环境因子的响应。结果发现, 夏季大亚湾淡澳河的输入使湾顶淡澳河口区域形成层化的低盐、高温、低透明度、高营养盐的水体, 湾中部表层水体则受一定强度河流羽流影响, 而湾口和湾中部底层水体主要受外海水影响。淡澳河淡水输入是夏季大亚湾外源性氮、磷营养盐的主要来源, 而硅酸盐除河流输入外, 外海水也输入较多的营养盐使得底层水体硅酸盐浓度较高。夏季大亚湾水体营养比例失衡较严重, 溶解无机磷是限制浮游植物生长的重要因子。硅藻是大亚湾夏季浮游植物的优势类群, 调查发现3种优势种[极小海链藻(Thalassiosira minima)、中肋骨条藻(Skeletonema costatum)和圆海链藻(Thalassiosira rotula)]均为硅藻。通过聚类分析, 可将大亚湾夏季浮游植物群落主要分为3种类型, 分别为: 浮游植物丰度较大的极小海链藻藻华暴发的群落, 位于淡澳河口, 受河流输入影响明显; 中肋骨条藻占据优势的群落, 分布在受一定强度的河流及其羽流影响的湾顶和湾中部区域; 浮游植物丰度较低的群落, 无明显优势种, 主要分布在湾口海水影响区域。淡澳河口的水体环境有利于小型链状硅藻极小海链藻的快速繁殖并暴发了藻华, 藻华发生时的海水环境条件为: 温度30~31°C, 盐度17‰~31‰, 水体透明度0.45~1.2m。硅藻对不同营养盐利用的差异以及随后的生物碎屑和颗粒沉降过程导致藻华发生区域Si∶N值略降低, N∶P值显著升高。河流输入影响下, 单一物种大量生长使得浮游植物群落种类组成丰度分布极不均匀, 从而导致淡澳河口浮游植物群落的种类多样性和均匀度指数降低, 种类多样性和均匀度指数均从淡澳河口向湾口逐渐增大。     

2017年春夏季西北太平洋浮游植物的区域差异及其与不同水团的关系

The West Pacific Ocean is considered as the provenance center of global marine life and has the highest species diversity of numerous marine taxa. The phytoplankton, as the primary producer at the base of the food chain,effects on climate change, fish resources as well as the entire ecosystem. However, there are few large-scale surveys covering several currents with different hydrographic characteristics. This study aimed to explore the relationships between the spatio-temporal variation in phytoplankton community structure and different water masses. A total of 630 water samples and 90 net samples of phytoplankton were collected at 45 stations in the Northwest Pacific Ocean(21.0°–42.0°N, 118.0°–156.0°E) during spring and summer 2017. A total of 281 phytoplankton taxa(5 μm) belonging to 61 genera were identified in the study area. The distribution pattern of the phytoplankton community differed significantly both spatially and temporally. The average abundances of phytoplankton in spring and summer were 797.07×10~2 cells/L and 84.94×10~2 cells/L, respectively. Whether in spring or summer, the maximum abundance always appeared in the northern transition region affected by the Oyashio Current, where nutrients were abundant and diatoms dominated the phytoplankton community;whereas the phytoplankton abundance was very low in the oligotrophic Kuroshio region, and the proportion of dinoflagellates in total abundance increased significantly. The horizontal distribution of phytoplankton abundance increased from low to high latitudes, which was consistent with the trend of nutrient distributions, but contrary to that of water temperature and salinity. In the northern area affected by the Oyashio Current, the phytoplankton abundance was mainly concentrated in the upper 30 m of water column, while the maximum abundance often occurred at depths of 50–75 m in the south-central area affected by the Kuroshio Current.Pearson correlation and redundancy analysis(RDA) showed that phytoplankton abundance was significant negatively correlated with temperature and salinity, but positively correlated with nutrient concentration. The phytoplankton community structure was mainly determined by nutrient availability, especially the N:P ratio.     

长江口理化因子影响初级生产力的探索Ⅰ.营养盐限制的判断方法和法则在长江口水域应用

营养盐限制浮游植物的生长是近年来国际研究的热点。探讨了目前营养盐限制的判断方法，认为仅靠氮和磷比值来得到磷限制或氮限制的结论是不完善的。根据营养盐限制的判断方法和法则，对长江口水域进行综合分析，认为在长江口及其附近海域，磷不是浮游植物生长的限制因子，而且氮、磷的浓度值都高于限制浮游植物生长的阈值，满足浮游植物的生长。通过1985年8月至1986年8月的长江口调查数据分析，发现从长江河口到远海水域的有些断面上，磷酸盐浓度并不一定离岸越远越低，且也没有周期性的季节变化。因此，尚须对河口区磷酸盐来源作进一步研究。     

Short-term variability of the phytoplankton community in coastal ecosystem in response to physical and chemical conditions' changes

The short-term dynamics (time scale of a few days) of phytoplankton communities in coastal ecosystems, particularly those of toxic species, are often neglected. Such phenomena can be important, especially since these very species can endanger the sustainability of shellfish farming. In this study, we investigated the short-term changes in phytoplankton community structure (species succession) in two coastal zones in parallel with physical and chemical conditions. Mixing events with allochtonous waters could thus be distinguished from local processes associated with population growth when it was associated with a change in light or nutrient limitation. Mixing events and water advection influenced fluctuations in total phytoplankton biomass and concentration of dominant species, while local processes influenced delayed changes in community structure. The estuarine species Asterionellopsis glacialis increased in concentration when the water mass mixed with the nearest estuarine water masses. The biological response, measured as photosynthetic capacity, occurred after a time-lag of a few hours, while the changes in community structure occurred after a time-lag of a few days. Finally, the coastal water mass was constantly mixed with both the nearest estuarine and marine water masses, leading in turn to delayed changes in phytoplankton community structure. These changes in species composition and dominance were observed on a time scale of a few days, which means that some toxic species may be missed with a bi-weekly sampling strategy.     

烟台四十里湾养殖水域营养盐的分布及动态变化

1997年5、8、11月及1998年3月对烟台四十里湾养殖水域营养盐的四个航次季节调查显示该水域营养盐的时空分布主要受陆源输入、养殖和自然生物活动及海流状况的影响。氮磷硅无机营养盐结构分析表明,烟台四十里湾春夏季硅限制了硅藻的生长;秋季氮为硅藻的相对限制因子,冬末春初硅是相对限制因子。     

Analysis of temporal and spatial variability of phytoplankton by physical-biological models

I reviewed my research on analysis of temporal and spatial variability of phytoplankton by physical-biological models. This paper was prepared for a lecture of the member awarded the Okada Prize for 1991 from the Oceanographical Society of Japan.Temporal change of phytoplankton in a local upwelling was studied by simulated upwelling experiments conducted with natural phytoplankton communities under natural surface light conditions. Results of the culture experiments was explained by a simple model. This model allows to predict the chlorophyll and nutrient concentration changes in a given upwelled water mass.Above model was verified by a local upwelling observed off Izu, Japan, on May, 1982. Phytoplankton growth and nutrient decrease in surface water of the local upwelling were observed within two days followed by decrease of phytoplankton concentration under depleted nutrient environment. The phytoplankton growth and nutrient decrease could explained by the model with phytoplankton removal rate of about half of the growth rate. Centric diatom was the dominant phytoplankton group and pennate diatom showed less abundance in the upwelled water. Pennate diatom showed fast growth rate when nutrient was abundant and fast decreasing rate after nutrient depleted. On the other hand, flagellate and monads showed relatively slow change of biomass under the change of nutrient concentrations. Furthermore, resting spore formation of centric diatom,Leptocylindrus danicus, was observed in a response to nutrient depletion.Temporal and spatial variability of phytoplankton in the southeastern U.S. continental shelf ecosystem was studied by physical-biological models. First, differences of the biological responses to frontal eddy upwelling during spring and to intrusion during summer was considered by Lagrangian particle tracing experiments with optimally-interpolated flow fields. In spring, particles showed residence time of a few days; however, particles in summer intrusion stayed on the shelf nearly 30 days. It was concluded that difference of particle residence time of upwelled water make the difference of plankton communities. Similar flow fields and particle tracing experiments were used to trace the features in chlorophyll distributions during spring of 1980 derived by Coastal Zone Color Scanner (CZCS). Phytoplankton patchness were created and deformed by frontal eddy events. Eularian physical-biological model was constructed to understand the CZCS-chlorophyll distributions. Statistical comparisons with series of numerical experiments indicate that horizontal advection is an important process for the chlorophyll distributions and that upwelling and associated phytoplankton growth are responsible for the across-shelf gradients and maintenance of concentrations. Furthermore, the CZCS data were assimilated to the model to improve the phytoplankton concentrations, and phytoplankton carbon flux across shelf was estimated. Processes causing the time changes of chlorophyll concentrations were estimated with the model and satellite data further indicated that the both physical and biological forcing is important for the time chages. Several other studies conducted presently were mentioned.