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1.
红海湾养殖水域营养盐消长与温度,盐度,浮游植物量的关系 总被引:1,自引:0,他引:1
红海湾海水养殖水域的营养盐,盐度,温度,浮游植物和叶绿素的观测结果表明,该 氨氮,亚硝酸盐及磷酸盐的消长受水系混合所制约。春季硝酸盐,氨氮和秋季磷酸盐与浮游植物之间的存在着负相关,秋季表层叶绿素与营养盐存在着正相关,而底层叶绿素与营养盐存在密切负相关。 相似文献
2.
【目的】研究珠江口海域营养物和叶绿素a的时空分布特征。【方法】根据2015年5月(春季)、8月(夏季)和10月(秋季)3个季节的现场调查资料,通过对3个季节浮游植物Chl-a以及包括氮磷比在内的营养结构进行综合分析,深入探讨珠江口海域浮游植物Chl-a的时空变化调控机制。【结果】珠江口海域各季节营养盐呈高氮低磷分布,3个季节N︰P均值49.6。叶绿素a季节差异明显,夏季叶绿素a含量是春季的2倍、秋季的9倍。【结论】春季浮游植物生长受温度影响较大,夏、秋两季由于外海水的入侵导致磷限制比较显著;DIN能满足各季节浮游植物生长的需要,珠江口海域浮游植物生长对于磷营养盐的响应要优于氮营养盐。 相似文献
3.
【目的】研究秋季雷州半岛海域东西部水体营养盐和叶绿素a(Chl-a)空间变化特征及其相互关系。【方法】根据2017年10月(秋季)的现场调查资料,分别采用镉铜柱还原-重氮偶氮法、重氮偶氮法和硅钼蓝法测定硝酸盐、亚硝酸盐、磷酸盐和硅酸盐,以及萃取荧光法测定Chl-a浓度,深入探讨雷州半岛Chl-a浓度空间变化的调控机制。【结果】2017年秋季,研究区域近岸Chl-a及营养盐浓度大致呈现近岸高离岸低的分布特点;雷州半岛东部海域与西部海域相比,Chl-a浓度、DIN、Si O32-,nDIN/nP比较高,而nSi/nDIN和PO43-在西部略高于东部;营养盐对浮游植物生长的可能限制因子分析结果,在雷州半岛东西部环境因子对Chl-a浓度的影响程度不同,其中盐度和亚硝酸盐是影响Chl-a浓度的主要因子。在浮游植物生长的限制因素方面,雷州半岛东部海域表现为明显的磷限制,西部海域表现为明显的氮限制。【结论】秋季调查海域营养盐和Chl-a结构变化主要受海域水文情况(河流径流,潮汐类型)和人类活动的影响。调查海域东部受到河流径流和不规则半日潮的影响,营养盐、Chl-a浓度以及营养盐比值(PO43-和nSi/nDIN除外)都比较高。西部海域由于河流径流量小、人类活动较少以及受到规则的全日潮的影响,营养盐、Chl-a浓度以及营养盐比值含量较低且分布较均匀。 相似文献
4.
【目的】分析珠江磨刀门河口浮游植物叶绿素a及其驱动因子的潮周期变化,并揭示叶绿素a的环境影响机制。【方法】基于珠江磨刀门河口2017年枯季(1月13-20日)水文水质多要素同步观测数据,采用主成分分析(PCA)和结构方程模型(SEM)确定浮游植物叶绿素a与多个环境因子的关系并量化各因子的驱动作用。【结果】磨刀门水道浮游植物叶绿素a浓度变化范围为0.77~10.92μg/L,口门处变化为0.70~9.01μg/L,磨刀门河口动力驱动下浮游植物叶绿素a的潮周期差异显著。盐度、含沙量和氮磷营养盐亦随潮汐涨落差异显著,而水温无明显潮周期变化。【结论】外海水团对氮营养盐的稀释混合作用强于磷营养盐,而悬浮泥沙对磷营养盐的吸附作用强于氮营养盐。与氮营养盐相比,溶解态磷相对不足,限制磨刀门河口浮游植物的生长。径流(营养盐、悬沙等为代表)、潮流(盐度为代表)对河口浮游植物的影响机制不同,其中氮磷营养盐和水温起着直接作用,而悬沙和盐度间接影响浮游植物叶绿素a的变化。 相似文献
5.
《广东海洋大学学报》2020,(3)
【目的】研究夏季珠江口水域氮、磷营养盐的时空变化特征及其富营养化水平。【方法】基于珠江口水域2006-2010年夏季水文水质多要素观测资料,采用Pearson相关分析法,分析水文泥沙对氮、磷等营养盐的的驱动作用,评价该水域富营养化状况并阐明其主要环境问题。【结果】珠江口水域环境因子区域分布差异显著,其中营养盐(氮、磷等)和悬浮泥沙均表现为由口门向口外递减,而盐度则表现为相反的趋势。无机氮以硝氮为主,亚硝氮次之,氨氮含量最低。【结论】径流输入、盐淡水混合稀释作用和悬浮泥沙的吸附/解吸作用共同影响着氮、磷营养盐的分布。氮磷比值分析说明,珠江口浮游植物生长主要表现为潜在性的磷限制。珠江口水域海洋环境重度及严重富营养化(E 5)主要集中在口门至内伶仃岛海域,主要环境问题为水质污染,且氮、磷营养盐和溶解氧为主要贡献因子。 相似文献
6.
根据1998年的现场调查资料,分析考洲洋海水无机营养盐与浮游植物生物量的平面分布及其相互关系,结果表明二者的关系很密切;浮游植物量在枯水期(2月)与无机氮,无机磷,硅酸盐显著正相关,相关系数分别为0.779,0.946和0.876(n=12);在丰水期(8月)与无机氮和硅酸盐负相关,与磷酸盐正相关,相关系数分别为-0.655,-0.845和0.584(n=11)。从浮游植物对营养盐的一般需要量和N,P,Si的原子比分析,2月N,P显得紧缺,8月N,P,Si均过量。 相似文献
7.
根据 1998年的现场调查资料 ,分析考洲洋海水无机营养盐与浮游植物生物量的平面分布及其相互关系。结果表明二者的关系很密切 :浮游植物量在枯水期 (2月 )与无机氮、无机磷、硅酸盐显著正相关 ,相关系数分别为 0 779、0 94 6和 0 876 (n =12 ) ;在丰水期 (8月 )与无机氮和硅酸盐负相关、与磷酸盐正相关 ,相关系数分别为 - 0 6 5 5、- 0 84 5和 0 5 84 (n =11)。从浮游植物对营养盐的一般需要量和N、P、Si的原子比分析 ,2月N、P显得紧缺 ,8月N、P、Si均过量 相似文献
8.
【目的】调查灌河口邻近海域生态环境状况。【方法】2016年5月对该海域进行水质、沉积物和生物生态现状调查。【结果与结论】水质主要超标因子为无机氮、磷酸盐;沉积物质量监测项目全部符合一类沉积物质量标准。浮游植物生物多样性指数丰富(3.11),浮游动物、游泳动物的生物多样性指数较丰富(大于2),底栖生物较贫乏(0.97)。底栖生物密度与沉积物硫化物显著正相关。浮游植物密度与叶素绿a显著正相关。小型网浮游动物密度与水温、化学需氧量显著负相关,其种类与营养盐、化学需氧量显著负相关,二者均与盐度显著正相关。 相似文献
9.
采用单因子实验方法研究氮、磷和硅营养盐对条纹小环藻(Cyclotella striata)生长和叶绿素a含量的影响。结果表明:在不同磷和硅营养盐浓度下,条纹小环藻比生长率μ变化显著(P<0.05),其中,硝酸盐为0.60~0.85 d-1,硅酸盐为0.49~0.61 d-1,磷酸盐为0.46~0.51 d-1。总体而言,在一定的营养盐浓度范围内,条纹小环藻的最大藻细胞密度Nmax随着氮、磷和硅营养盐浓度的增加而增大;条纹小环藻叶绿素a(Chl a)含量亦随着氮、硅浓度的增加,与Nmax增加趋势一致,但随着磷浓度的增加Chl a先增加后减小,与Nmax不一致。条纹小环藻的主要限制营养元素是氮和硅,而磷可能不会成为其短期培养的限制因子。 相似文献
10.
综合分析中国近海不同海域浮游植物的时空分布和季节变化特征研究,概述该海域浮游植物叶绿素和初级生产力研究。受复杂的物理环境场、生物地球化学作用等综合影响,不同海域Chl-a和初级生产力具有显著的时空变化特征:空间上,叶绿素浓度表现为近岸高离岸低、离岸海域随纬度增加呈升高趋势;时间上,大体呈现明显的季节变化特征,北部季节特征尤为明显,其中叶绿素浓度及生产力的季节最大值在南海出现在冬季,而在中国北部海域逐渐变化为春季。影响浮游植物生长的主要因素有营养盐、温度、光照、陆源输入、季风、环流、涡旋等,不同海域、不同季节浮游植物生长的限制因子有差异。另外,由于遥感数据的精度以及现场观测航次的频率较低和站位布置较为稀疏影响了上述机制的探讨,因而浮游植物生长的主要调控机制仍待进一步研究。 相似文献
11.
徐闻珊瑚礁保护区营养盐时空分布特征 总被引:2,自引:1,他引:1
2006年8月(夏季)、2006年11月(秋季)、2007年2月(冬季)和2007年4月(春季)在徐闻珊瑚礁自然保护区灯楼角至流沙湾近岸海域调查徐闻珊瑚礁保护区的营养盐变化及空间分布特征。结果表明:徐闻珊瑚礁保护区水域溶解态无机氮以NO3--N为主,其含量超过总溶解无机氮的50%;各站点NO2--N含量相对较低,冬季NO3--N和NH4+-N含量均高于其它季节;无机磷含量在0mg/L~0.030mg/L之间变化;活性硅含量表现为夏秋季节高、冬春季节低;表层水体硝酸盐氮/无机磷原子比值(N/P)夏季较低,不存在无机磷受限情况,而冬季N/P整体较高,此时水体主要受无机磷限制。 相似文献
12.
Tempo-spatial variation of nutrient and chlorophyll-α concentrations from summer to winter in the Zhangzi Island Area (Northern Yellow Sea) 总被引:1,自引:0,他引:1
Nutrient and Chlorophyll-a (Chl-a) concentrations were investigated monthly along three transects extending from a mariculture area to open waters around the Zhangzi Island area from July to December 2009. The objective of this study is to illustrate food availability to the bottom-sowed scallop Patinopecten yessoensis under the influences of the Yellow Sea Cold Water Mass (YSCWM), freshwater input and feedbacks of cultivated scallops. Significant thermal stratification was present in open waters from July to October, and salinity decreased in July and August in surface layers in the mariculture area. Nutrient concentrations increased with depth in both areas in summer, but were similar through water column in November and December. On average, nutrient increased from summer to autumn in all components except ammonia. Nutrient concentrations lower than the minimum thresholds for phytoplankton growth were present only in upper layers in summer, but stoichiometric nitrogen limitation existed in the entire investigation period. Column-averaged Chl-a concentration was lower in open waters than in mariculture area in all months. It increased significantly in mariculture area in August and October, and was less variable in open waters. Our results show that nutrients limitation to phytoplankton growth is present mainly in upper layer in association with stratification caused by YSCWM in summer. Freshwater input and upwelling of nutrients accumulated in YSCWM can stimulate phytoplankton production in mariculture area. Farming activities may change stoichiometric nutrient ratios but have less influence on Chl-a concentration. 相似文献
13.
ZHANG Guangtao ZHAO Zengxia LIU Changhua LIU Qun and REN Jianming Jiaozhou Bay Marine Ecosystem Research Station 《中国海洋大学学报(英文版)》2012,(3):419-426
River discharge can deliver nutrients to the coastal zone and change the hydrologic properties of the water column. Soon after a flash flood from the Yalu River (Northeast China) in August 2010, we investigated the salinity and nutrient concentrations, as well as other environmental conditions in the Changshan Archipelago area, located approximately 100 km west of the river mouth in the northern Yellow Sea. Diluted water was mainly observed in the upper layers shallower than 15 m, with surface salinity between 18.13 and 30.44 in the eastern study area and between 28.16 and 29.72 in the western area. Surface salinity showed a significant negative correlation with concentrations of dissolved nutrients (P < 0.05), but not with that of Chlorophyll-a (Chl-a), dissolved oxygen (DO), particulate materials or pH. The average concentrations of nitrite, nitrate, and silicic acid decreased from the surface layer to bottom layer and were significantly higher in the east area than in the west area (P < 0.05). In contrast, average ammonium and phosphate concentrations were highest in the bottom layer of both areas, with no significant spatial differences. DO varied between 6.06 and 8.25 mg L-1 in the surface layer, and was significantly higher in the eastern area than in the western area in the surface and middle layers. Chl-a concentration was constantly below 4.09 μg L-1. Our work demonstrated the strong influences of Yalu River on proportions of various nutrient components in the Changshan Archipelago area. Silicic acid and total inorganic nitrogen levels were significantly elevated comparing to phosphate in the eastern area. Such changes can potentially induce phosphate limit to phytoplankton growth. 相似文献
14.
A simple diagnostic simulation of the annual cycling of the surface specific photosynthesis rate (SPR) in Jiaazhou Bay is described in this paper. Light intensity, temperature and nutrients(nitrate ammonia, phosphate) were considered as main factors controlling photosynthesis of phytoplankton and were introduced into the model by different function equations. The simulated variation ofspecific photosynthesis rate coincided with the measured data. Analysis of the effect of every factor onphotosynthesis indicated that the variation of photosynthesis rate was controlled by all these three factors,while temperature showed good correlation with SPR as measurement showed. This diagnostic simulationyielded the values of some parameter relating with the photosynthesis in Jiaozhou Bay. 相似文献
15.
INTRODUCTIONPhosphorusisakeynutritiveelementforthegrowthofmarinephytoplankton .Recently ,be causeofenvironmentalpollution ,theeutrophicationproblemsincoastalandoceanicwatershavebe comemoreandmoreserious.Theenvironmentecologicalresponseinthelong termtothef… 相似文献
16.
The results of an investigation carried out during June 2005 to May 2007 on bloom-forming phytoplankton species composition and abundance in the Parangipettai and Coleroon coastal waters(Southeast coast of India) are reported.Air and surface water temperatures(℃) varied from 25.1 to 30.1 and 24.5 to 28.5,respectively,in the former waters and from 25.5 to 31.2 and 25.0 to 29.3 in the latter waters.The respective salinities varied from 6.0 to 28.5 and 5.0 to 33.1 and the respective pH ranged between 7.0 and 8.3 and 7.2 and 8.3.Correspondingly,the dissolved oxygen content varied from 3.1 to 7.5 and 3.1 to 7.9 mgL-1 while the light extinction coefficient(LEC) values ranged between 3.1 and 10.1 and 1.8 and 11.0.The content ranges of inorganic nutrients,i.e.,nitrate,nitrite,phosphate and silicate(μmolL-1),in the Parangipettai and Coleroon coastal waters were:6.5-27.0;1.0-8.9;0.1-3.0 and 15.0-140 and 10.1-23.4;1.2-8.9;0.2-3.1 and 55-125 respectively.The chlorophyll a contents in both waters ranged from 2.0-7.5 μgL-1.Presently,124 phytoplankton species representing different classes were recorded in the Coleroon coast,viz,Bacillariophyceae(77);Dinophyceae(19);Cyanophyceae(15);Chlorophyceae(10) and Chrysophyceae(3),whereas 117 phytoplankton species were recorded in the Parangipettai coast,viz,Bacillariophyceae(66);Dinophyceae(22);Cyanophyceae(19);Chlorophyceae(7) and Chrysophyceae(3).The phytoplankton cell abundance in the Parangipettai and Coleroon coastal waters varied from 290 to 111662 and 140 to 132 757 cells L-1,respectively,with peak diversity(3.38 and 3.52 bits ind-1.) recorded in summer.The maximum abundance occurred in summer coinciding with the stable hydrographical conditions.The seasonal distribution and abundance of phytoplankton are discussed in relation to hydrographical parameters.Totally 31 and 24 species of phytoplankton were found to be bloom-forming in the Parangipettai and Coleroon coastal waters,respectively.Presently Trichodesmium bloom was also observed,which appeared at the 10 fathom level of the coastal water and quickly spread to the marine zone of the Vellar estuary and near the mouth region of the mangrove waters.The Parangipettai and Coleroon coastal waters are subject to long term fluctuations in physico-chemical conditions depending upon the seasonal tidal range and freshwater influx,resulting in a continuous exchange of organic,inorganic,plant and animal matters. 相似文献
17.
18.
The investigation shows that the concentrations of nutrients are high in estuarine and coastal waters and low in offshore
waters. The concentration of nitrate in estuaries is controlled through a physical mixing process and is also affected by
biotic activity. The annual transport of total inorganic nitrogen and dissolved phosphate-phosphorus from the Huanghe River
water to the sea is about 8.45 ×104 and 1.45×103 tons respectively. The distributions of inorganic nitrogen and silicate in interstitial water of surface sediments are similar
to those in surface and bottom seawater. Their contents in interstitial water are 227–552 μmol/l (average375) for ammonia,
0.31–9.0 μmol/l (average 1.6) for nitrite, 0–41 μmol/l (average6.0) for nitrate, and 41–139 μmol/l (average 77) for silicate.
The average concentrations of phosphate in the surveyed area are 0.64 μmol/l for seawater and 1.2 μmol/l for interstitial
water. A cycle of phosphate in the estuary is also suggested in this paper.
Contribution No. 1434 from Institute of Oceanology, Academia Sinica. 相似文献
19.
A severe Cochlodinium geminatum red tide (>300 km2) was observed in the Zhujiang (Pearl) River estuary, South China Sea in autumn 2009. We evaluated the environmental conditions and phytoplankton community structure during the outbreak. The red tide water mass had significantly higher dissolved inorganic phosphate (DIP), ammonia, and temperature, but significantly lower nitrite, nitrate, dissolved inorganic nitrogen (DIN), and DIN/DIP relative to the non-red-tide zones. The phytoplankton assemblage was dominated by dinoflagellates and diatoms during the red tide. C. geminatum was the most abundant species, with a peak density of 4.13×107 cell/L, accounting for >65% of the total phytoplankton density. The DIN/DIP ratio was the most important predictor of species, accounting for 12.45% of the total variation in the phytoplankton community. Heavy phosphorus loading, low precipitation, and severe saline intrusion were likely responsible for the bloom of C. geminatum. 相似文献