共查询到19条相似文献,搜索用时 140 毫秒
1.
南黄海冷水域西部溶解氧垂直分布最大值现象的成因分析 总被引:1,自引:2,他引:1
重点分析了南黄海冷水域西部溶解氧(DO)垂直分布中的最大值现象,并对DO浓度与主要环境因子的相关性进行了研究.结果表明:DO垂直分布最大值现象是调查海域DO分布的显著特征,且与SCM现象相伴生;DO垂直分布的最大值深度和量值具有较为明显的区域差异;温、盐是DO最大值层以上水体中氧含量的主要控制因素;一定强度的温跃层形成之后,DO最大值层出现在跃层的下界附近,且其氧含量受控于跃层厚度和生物化学作用,并与跃层厚度呈正相关;底层较低的DO含量是底层水及沉积物中有机物分解耗氧的结果.同时,还成功解释了DO最大值处与次表层叶绿素最大值层位置不吻合且量值不相关的原因,并提出了"DO净积累效应"的观点,不仅从时间跨度以及动态的角度上对DO最大值的形成机制进行了分析,而且从理论上探讨了DO最大值层氧含量(或来源)的构成,指出自DO最大值层开始产生至观测之时该层之下、真光层以内水体中的生物化学作用(或Chl-a总产出)才与氧最大值密切相关.总体来看,水体层化和生物化学作用明显影响着夏季南黄海冷水域西部DO的垂直分布. 相似文献
2.
3.
南黄海物理-生物地球化学过程的时空异质性及内在关联和机制 总被引:2,自引:0,他引:2
研究多重物理过程控制下陆架边缘海生物地球化学过程的时空异质性及其生态响应,对于深入认识海洋生态系统具有重要的意义。基于相关历史观测资料和卫星遥感海表温度,本文综合分析了南黄海物理-生物地球化学过程的时空变化和空间异质性特征,探讨了该海域内部典型地理单元之间的内在关联和机制。结果显示,冷季沿岸流南向输送和暖季锋面上升流垂向输运的季节性交替是影响石岛外海与海州湾外侧海域生物地球化学和初级生产的重要物理过程。夏季苏北沿岸水的东北向扩展可形成浒苔离岸/跨区域输送的动力驱动。暖季水体层化显著影响着南黄海中部冷水团海域的生物地球化学过程,春至秋季冷水团海域底层水体中的营养盐逐渐累积,形成了营养盐的重要贮库;层化季节黄海冷水团边界锋区上升流系统的存在使得南黄海叶绿素a和初级生产力高值区位置同海表低温涌升流区总体相一致。冷季南黄海西部南下的冷水与中部北向入侵的暖水共同导致了“S”型锋面的形成;暖季黄海冷水团边界锋区的上升流系统是连接层化海域和近岸区的纽带,可实现对冷水团内部营养盐的提取,从而将冷水团内部和边界区的生物地球化学过程形成有机连接,并在成山角-石岛外海、海州湾外侧、苏北浅滩东部形成三个典型的物理-生物地球化学相互作用区。本研究细化和整合了南黄海区域海洋学研究,揭示了该海域物理-生物地球化学过程的空间异质性特征和不同地理单元之间的关联性及机制,获得了对南黄海水文-生物地球化学-生态过程的综合、系统认知。 相似文献
4.
基于2017年4月、5月、6月和8—9月在南黄海西部海域4个航次的现场调查,分析了春至夏季逐月的营养盐分布特征及其影响因素,初步探讨了营养盐与浒苔绿潮暴发的关系。结果表明:春至夏季苏北近岸浅水区总体呈现出高温、低盐、高营养盐的特征,且各理化要素垂向差异不明显;同时该海域表层水体中的营养盐含量自4月至5月有所下降,而后开始上升,至8—9月达到最大浓度。受长江冲淡水的影响,调查海域西南部表层存在向东北方扩展的低盐、高营养盐水体,在夏季与苏北海域向外扩展的营养盐高值区连成一体。在调查海域的中部至东北部深水区,入春后表层海水不断升温,至夏季于底层形成显著的黄海冷水团,并在其周围呈现出锋面特征;受初级生产过程和温跃层的影响,入春后该海域的上层营养盐浓度总体呈现出下降的趋势并在夏季维持了较低的水平,而底层营养盐浓度从春季至夏季有所升高且影响范围不断向西南方向扩展,至8—9月达到最大范围。苏北近岸海域丰富的营养盐为入春后大型藻类的生长和暴发提供了重要的物质基础,而且5月南黄海西部相关海域表层营养盐浓度降低与浒苔、马尾藻等大型漂浮藻类暴发对营养盐的吸收利用有关。 相似文献
5.
夏季南黄海海水化学要素的分布特征及影响因素 总被引:8,自引:0,他引:8
基于2006年7月对南黄海调查所得资料,对南黄海海水化学要素的分布特征及影响因素进行了探讨.结果表明:(1) 调查海域底层122°E~123°E,33°N以南范围内存在明显的DO亏损现象,证实了长江口外低氧区向南黄海的扩展态势.(2) 南黄海西南部上层水体中的营养盐主要来源于长江冲淡水及苏北沿岸流的输运,且营养盐与盐度之间呈较好的负相关,具有一定的保守性,同时发现表层无机氮盈余状况的分布与该海域环流的扩展途径密切相关;南黄海西南部底层东北向的高营养盐水舌是长江冲淡水、台湾暖流前缘水以及底层有机物分解释放营养盐综合作用的结果;南黄海冷水域因有机物分解而积聚了大量营养盐.(3) 根据南黄海冷水域海水化学要素的断面分布,指出自DO最大值层开始产生至观测之时该层之下、真光层以内光合作用产氧在温跃层下界的积累和保存在氧最大值形成过程中具有极其重要的作用. 相似文献
6.
南黄海溶解氧垂直分布上的中间高氧层及其最大值是黄海冷水团区的一个突出现象。毛汉礼等(1964)认为:在夏季,凡是黄海冷水盘踞的地方,几乎都有一个中间高氧层,其深度与温跃层有关,大致都在温跃层的下界附近;中间高氧层可作为黄海冷水的一项指标。后来,顾宏堪(1966, 1980)专题讨论了黄海的夏季溶解氧垂直分布中最大值问题。他认为这一最大值主要是由冬季保持而来。但是,由于当时的资料垂向取样间隔大,因而对冷水团区溶解氧的垂直结构及其分布特征等问题没有进行详细的讨论。
本文试图在前人工作的基础上,利用1983年11月中美南黄海环流和沉积动力学联合调查所获取的CTD资料,和与其同步取样(每秒钟抽样一次,深度间隔约在0.3-0.8m之间)的溶解氧资料,对秋末南黄海冷水团区溶解氧垂直结构及其最大值分布特征,以及它们同水系的关系等问题作进一步的分析研究。
调查海区和站位分布如图1所示。由于种种原因,调查海区仅限制在124°30''E以西海域,这对研究上述问题,特别是同水系的关系,带来了一定的困难。 相似文献
7.
黄海冷水域生源要素的变化特征及相互关系 总被引:41,自引:8,他引:33
根据“中韩黄海水循环及物质通量合作研究”项目的现场调查资料,对黄海冷水域生源要素的分布变化特征及其相互关系进行了探讨。结果表明,黄海冷水团存在期间,上层水体中的营养盐由于浮游植物的摄取而几乎被耗尽,但在密度跃层以下因有机物分解使营养盐再生而逐步累积。溶解氧、pH和叶绿素a的层化现象亦十分明显,并在中层(20~30m)形成最大值层。生源要素断面分布中等值线的起伏趋势或马鞍形形态表明,黄海冷水团中的垂直环流存在将底层冷水向上扩散的趋势。此外,对影响生源要素的含量、分布及其季节变化的因素,以及生源要素之间的相互关系进行了分析探讨。 相似文献
8.
根据2006年北黄海夏季航次调查资料,初步估算夏季冷水团及整个调查海区的水体体积,进而分别计算两者的营养盐总量,并在此基础上估算夏季冷水团区营养盐对调查海域的贡献.结果表明冷水团作为营养盐的高值区,以仅占调查海区总体积23.7%的体积分数,达到了对DIN、PO4-P和SiO3-Si分别为46.3%、63.9%和32.1%的贡献率,尤其是PO4-P的贡献量,更是达到海区总量的一半以上,充分体现出其营养盐贮库,特别是PO4-P贮库的特性.在水体层化减弱、消失的季节,冷水团对整个水体的营养盐是极大的补充. 相似文献
9.
黄海潮生陆架锋的分布 总被引:4,自引:0,他引:4
潮汐的搅拌作用,即潮混合,常常在中纬度陆架浅海中形成一种重要的水文现象——浅水陆架锋,亦称潮汐锋。黄海是一个半封闭的中纬度陆架浅海,水温的季节变化非常显著。黄海的潮能消耗又非常可观。据此,作者指出:夏季黄海的层化现象与潮混合有关;年复一年,黄海冷水团边界基本稳定,并且在冷水团边界附近海面总是存在着一些冷水分布,这类现象也是由潮混合形成的;由于近岸冷水的形成,在黄海冷水团边界附近海面还存在着浅水陆 相似文献
10.
北黄海典型断面生源要素四季变化的研究 总被引:1,自引:0,他引:1
在2006年7月至2007年10月对北黄海两个典型断面4个航次调查的基础上,分析并讨论了两断面上生源要素的分布情况及其四季变化.结果表明DO的含量与饱和度自春至冬,呈现先降低后升高的趋势,在秋季降至最低点;而PO4-P和DIN的含量,亦是先减小后增大,其浓度的极低值出现在夏季;SiO3-Si的季节变化趋势有所不同,自春季至冬季,它呈现逐渐增大的变化趋势.此外,自春季开始形成,至秋季消亡的黄海冷水团是海区中部重要的营养盐贮库. 相似文献
11.
南黄海秋季叶绿素a的分布特征与浮游植物的固碳强度 总被引:19,自引:5,他引:19
依据2005年10月中下旬对南黄海的调查结果,系统阐述了2005年秋季南黄海叶绿素a的分布特征,并估算了南黄海和东中国近海初级生产力水平及浮游植物固碳强度,分析了控制其变化的生物地球化学机制.结果表明,南黄海表层叶绿素a含量的变化范围为0.11~2.38 mg/m3,平均浓度为0.66 mg/m3,明显高于50 m层的含量.南黄海表层和次表层叶绿素a分布趋势基本一致,均显现出西北高、东南低的趋势,在近岸海域出现显著的高值带,这主要是由于受到陆源输入和沿岸流带来的高营养盐的影响;中部海域的低值区则主要受控于来自东海低营养盐海流的“冲淡”作用.在垂直分布上,叶绿素a最高值基本出现在次表层,与以往发现的该海域次表层溶解氧最大值一致,这显然与南黄海浮游植物及区域水团特性有关.2005年秋季南黄海初级生产力(C)变化在95~1 634 mg/(m2·d),平均为586 mg/(m2·d),其分布趋势显示了海洋初级生产力与海水磷浓度以及水团、海流的关系.应用初级生产力估算的浮游植物固碳强度的结果表明,我国东部近海浮游植物年总固碳量约为222Mt,约占全球近海浮游植物的年固碳量的2.0%,为我国东部近海通过海-气界面总表观碳汇强度每年1 369万t的16.2倍,在不同的海域,浮游植物固碳量是其通过海-气界面总表观碳汇强度的倍数不同(渤海为3.0倍,黄海为6.7倍,东海为81.6倍). 相似文献
12.
The spatial and temporal variability of the chlorophyll (Chl) concentration in the surface water layer of the Black Sea in 1998–2008 has been analyzed using the data obtained by the SeaWiFS satellite sensor. In the deep-sea areas, the seasonal pattern of the Chl concentration is represented by a U-shape curve. The maximal concentrations are observed in the winter-spring and autumn periods, while the minimal, in the summertime. In the northwestern Black Sea, the maximal concentrations are registered in mostly the summer and autumn periods. Pronounced interannual variability is found for the summer concentrations of Chl observed for an 11-year period. After a cold winter, the concentration of Chl in the spring period is 3–5 times higher compared to the mild-winter years. In December–March, a negative correlation between the water temperature and the average Chl concentration is registered. 相似文献
13.
14.
Nutrients, chlorophyll-a, particulate organic carbon (POC), and environmental conditions were extensively investigated in
the northern East China Sea (ECS) near Cheju Island during three seasonal cruises from 2003 to 2005. In spring and autumn,
relatively high concentrations of nitrate (2.6~12.4 μmol kg-1) and phosphate (0.17~0.61 μmol kg-1) were observed in the surface waters in the western part of the study area because of the large supply of nutrients from
deep waters by vertical mixing. The surface concentrations of nitrate and phosphate in summer were much lower than those in
spring and autumn, which is ascribed to a reduced nutrient supply from the deep waters in summer because of surface layer
stratification. While previous studies indicate that upwellings of the Kuroshio Current and the Changjiang (Yangtze River)
are main sources of nutrients in the ECS, these two inputs seem not to have contributed significantly to the build-up of nutrients
in the northern ECS during the time of this study. The lower nitrate:phosphate (N:P) ratio in the surface waters and the positive
correlation between the surface N:P ratio and nitrate concentration indicate that nitrate acts as a main nutrient limiting
phytoplankton growth in the northern ECS, contrary to previous reports of phosphate-limited phytoplankton growth in the ECS.
This difference arises because most surface water nutrients are supplied by vertical mixing from deep waters with low N:P
ratios and are not directly influenced by the Changjiang, which has a high N:P ratio. Surface chlorophyll-a levels showed
large seasonal variation, with high concentrations (0.38~4.14 mg m-3) in spring and autumn and low concentrations (0.22~1.05 mg m-3) in summer. The surface distribution of chlorophyll-a coincided fairly well with that of nitrate in the northern ECS, implying
that nitrate is an important nutrient controlling phytoplankton biomass. The POC:chlorophyll-a ratio was 4~6 times higher
in summer than in spring and autumn, presumably because of the high summer phytoplankton death rate caused by nutrient depletion
in the surface waters. 相似文献
15.
南沙群岛海域溶解氧垂直分布最大值的季节特征 总被引:5,自引:1,他引:5
根据“八五”、“九五”国家科技专项南沙群岛海域综合科学考察的现场调查资料,对南沙群岛海域溶解氧垂直分布最大值现象的分布特征、季节变化规律作了较为全面的分析和研究,同时比较了东海、黄海海域春、夏季溶解氧垂直分布出现的最大值现象及其特征.研究结果表明南沙群岛海域溶解氧垂直分布的最大值现象与我国东海、黄海海域的溶解氧垂直分布最大值现象无论在地理分布、深度、强度、季节性变化还是存在条件的特征化方面,均有着较大的差别.反映影响南沙群岛海域溶解氧垂直分布最大值形成的原因,均与东海、黄海海域溶解氧垂直分布最大值形成的原因有所不同 相似文献
16.
Vertical distributions of turbidity & phytodetritus (Chl.a and pheopigment), and their seasonal variations were measured in the deep water column of Sagami Bay, Japan, in June 1999, February 2000 and May 2000. Observations were carried out at eight stations along an east-west section of Sagami Bay using a CTD/water sampling system equipped with a memory-type infrared back-scattering meter which had been calibrated for the suspended particles collected in Sagami Bay. Turbidity increased close to the bottom in both summer and winter, indicating the existence of a benthic nepheloid layer throughout the year. But the vertical gradient of turbidity was much larger in summer than in winter. The concentration of Chl.a and pheopigment also increased in the benthic layer in summer, sometimes reaching values of more than 0.01 and 0.2 μg/l, respectively, much higher than those reported in hemipelagic regions of the ocean. In winter, on the other hand, Chl.a kept a constant low value throughout the deep water column. This indicates that the turbid water mass formed in the benthic layer in summer derives from the deposition of large amounts of phytodetritus in spring and the resuspension of these aggregates, which are subsequently decomposed in the benthic layer during the following autumn. Unlike the benthic boundary layer, the turbidity of intermediate water was lower in summer rather than in winter. Because the phytoplankton aggregates exported from the surface water during the spring bloom not only supply phytodetritus to the benthic layer but also scavenge the suspended particles in the water column, the steep vertical gradient of turbidity observed in summer may reflect the dynamic interaction between suspended and sinking particles in the deep water column. 相似文献
17.
A spatial and temporal variation in physiochemical parameters in the southeastern Yellow Sea(YS) is investigated in the spring and summer of 2009 to 2011.Nutrient show a strong negative relationship with chlorophyll a(Chl a) concentration in spring,and the subsurface chlorophyll a maxima(SCM) layer was associated with the nitracline in summer.In summer,the SCM was usually found within or above the pycnocline and at the depths of shoals from the open sea to the coastal sea due to tidal and/or topographical fronts in the southernmost study area.High Chl a concentrations were found in the central southern YS,where the YS cold water layer expanded under the pycnocline and encountered water masses during spring and summer.After a typhoon in the summer of 2011,Chl a concentration increased,especially in the central southern YS,where cold waters occurred below the pycnocline.The results suggest that the development of thermohaline fronts may play an important role in the growth and accumulation of phytoplankton biomass in the upper layer of the southeastern YS during spring and summer. 相似文献
18.
南黄海悬浮体浓度的平面分布特征及其输运规律 总被引:3,自引:1,他引:2
重点分析和探讨了南黄海悬浮体浓度的平面分布及其水平输运,结果显示悬浮体浓度具有显著的空间区域化分布特征,其与该海域环流场的布局和季节转换存在良好的对应关系,南黄海环流是该海域悬浮体运移的主要动力和控制因素;江苏近岸海域在一年四季均为悬浮体浓度的最高值区,其悬浮体主要来源于潮流和海浪所引起的沉积物再悬浮以及苏北沿岸水的携带和输送,而且夏季悬浮体在该海域的累积还可为冬半年在黄海西部沿岸流作用下将其输运至东南海域提供很好的物源保证;长江口东北部海域在春、夏、秋三季出现东北向扩展的高值区,体现了长江冲淡水的影响;石岛外海在冬、春、秋三季也存在悬浮体浓度高值区,并具有向南黄海中部泥质区扩展的态势,这是鲁北沿岸流将现代黄河物质输运至此的结果。发现调查海域中部表底层在春秋季均存在云团状高值区,而且该海域悬浮体浓度自春季至秋季出现"双峰现象",这与春秋季水华期间浮游植物繁殖所产生的有机碎屑有关,并使作为悬浮体组成的海洋浮游生物有机质向沉积物转移,据此进一步指出这一物源可能对南黄海冷涡泥质区的形成、发育也具有一定的作用,该观点深化了对南黄海中部冷涡泥质区受上层生物活动影响以及泥质区物源的认识。 相似文献
19.
The seasonal circulation in the southeastern Huanghai Sea has been studied with hydrographic data,which were observed in February and June 1994 and bimonthly during 1970-1990,and numerical model results.Horiwntal distributions of temperature and salinity in 1994 are quite different due to strong tidal mixing so that we need a analysis to see the real distributions of water masses.The mixing ratio analysis with the data of 1970-1990 shows the connection of the waters in the west coasts of Kotea Peninsula with warm and saline waters from the south in summer,which means northward inflows along the west coasts of Korea Peninsula in summer.With this flow,the seasonal circulations,which are deduced from the seasonal change of water mass distributions in the lower layer,are warm inflows in winter and mld outflows in summer in the central Huanghai Sea,and cold outflows in winter and warm inflows in summer along the west coasts of Korea Peninsula.The seasonally changed inflows might be the Huanghai Sea Warm Current.The monsoon winds can drive such circulations.However,summer monsoon winds are weak and irregular.As one of other possible dynamics,the variation of Kuroshio transport is numerically studied with allowing sea level fluctuations.Although it should be studied more,it possibly drives the summer circulations.The real circulations seem to be driven by both of them. 相似文献