南海北部海区水团分析

以模糊聚类为主要方法,在南海北部海区划出8个水团:沿岸冲淡水团(F)、近岸混合水团(M)、暖表层水团(WS)、表层水团(S)、表-次层混合水团(SU)、次层水团(U)、次-中层混合水团(UI)和中层水团(I).对各水团的形成、基本特征、变性特点以及消长变化和分布规律进行了综合分析.可将它们分为3种类型:径流冲淡型——F,浅海变性型——M、WS、S、SU和深海大洋型——U、UI和I.     

南海北部海区水团分析

以模糊聚类为主要方法,在南海北部海区划出8个水团:沿岸冲淡水团(F)、近岸混合水团(M)、暖表层水团(WS),表层水团(S)、表次层混合水团(SU)、次层水团(U)、次中层混合水团(UI)和中层水团(I).对各水团的形成、基本特征、变性特点以及消长变化和分布规律进行了综合分析.可将它们分为3种类型:径流冲淡型——F,浅海变性型--M、WS,S、SU和深海大洋型——U、UI和I.     

南海北部海区水团的判别分析

一、引言判别分析,是多元分析的一支,近年来,发展甚为迅速。笔者曾将二级判别及逐次二级判别,用于东海水温及渔场预报。它在气象、地质、医学等各个学科的应用更为广泛,而水团分析方面的应用,尚未见报道。本文就此作点尝试。我们使用1980年的资料,对南海北部海区的水团进行了模糊聚类分析,并用软划分方法     

南海北部海区水团的判别分析

将判别分析应用于南海北部海区的水团分析。划分为八个水团:沿岸冲淡水团(F),近岸混合水团(M),暖表层水团(WS),表层水团(S),表—次层混合水团(SU),次层水团(U),次—中层混合水团(UI)和中层水团(I)。给出了各水团在四季代表月的Bayes多组判别的系数和参数。用资料检验判别的成效.冬季和春季可达95.90％以上,夏季为94.80％,秋季是全年最低值,为92.72％。讨论了造成错判的原因,并与Fisher判别作了比较。当测值维数较低时,建议选用Bayes判别。对八个水团以及各水团两两之间差异的显著性进行了检验,证实在每个季节中各水团之间的差异,都在高度置信水平(α=0.01)上具有显著性。因而,划分为八个水团是有实际意义的,其判别式的系数和参数,可用于实际的判别和预报。     

模糊数学方法在南海北部海区水团分析中的应用

本文将模糊数学的多种方法,用于南海北部海区的水团分析.在用模糊聚类方法划分水团时,提出了基于欧氏距离的相似关系,同时提出了基于F-检验而决定水团个数的方法.以模糊聚类划出的水团为基础,再用软划分方法,对水团边界和测样归属进行合理调整.根据上述结果及区域海洋学的分析,在该海区划出了8个水团:沿岸冲淡水团F、近岸混合水团M、暖表层水团WS、表层水团S、表次层混合水团SU、次层水团U、次中层混合水团UI和中层水团I.将各类水团在-S图解上的点集,归结为变形椭圆凸点集、半无界凸点集和单侧凹点集3种类型.分别提出了建立相应隶属函数的方法,并给出了拟合结果.计算了各季节各水团的熵,讨论了高熵和低熵水团的特征及形成原因.计算了各季节不同水团之间的格贴近度,借以讨论水团变性的特点和它们之间的相互关系.可将8个水团归纳为3种类型:径流冲淡型(F),浅海变性型(M、WS、S和SU),深海大洋型(U、UI和I).     

模糊数学方法在南海北部海区水团分析中的应用

Some methods of fuzzy sets are applied to the analysis of water masses in the north area of the South China Sea. In distinguishing water masses with the fuzzy clustering method, the authors propose a fuzzy similar relation based on Euclidean distance, and suggest a method for determining the number of water masses by the F-test, and further adjust rationally the boundaries of water masses and the membership relation of samples by the elastic classification method. Eight water masses are distinguished in the area, i.e., Nearshore Diluted Water F, Nearshore Mixed Water M, Warm Surface Water WS, Surface Water S, Surface-Subsurface Mixed Water SU, Subsurface Water U, Subsurface- Intermediate Mixed Water UI and Intermediate Water I. These point-sets of various water masses on the θ-S diagram may be summed up in three types, that is, the deformed elliptical convex point-set, the half-boundless convex point-set and the point-set with single-side concave. For them, we have proposed methods of making their memb     

1998年夏季南海水团分析

根据 1 998年夏季“南海季风试验 ( SCSMEX)”期间所获的 CTD资料 ,使用系统聚类、Fuzzy模式聚类、Bayes判别分析和 Fuzzy分析等水团分析方法 ,对南海水体的结构和水团配置状况等进行了分析 ,划出了南海存在的 9个主要水团 ,并对各水团的温、盐度特征进行了初析。在调查期间 ,南海本地水 (南海水 )几乎控制了整个调查海区 ,而黑潮水仅出现在台湾岛的西南海域 ;海水强烈混合发生在吕宋海峡附近 ;在中南半岛以东和吕宋岛以西海域 ,表层水明显下沉 ;在南海东南部可能有来自苏禄海的海水 ,其温、盐度特征类似于吕宋海峡中的黑潮水     

南海北部及巴士海峡附近的水团分析

为解释黑潮水进入南海的方式 ,通过对 2 0 0 2年 5月 2 9日～ 6月 6日在南海及巴士海峡附近太平洋海域观测所得的资料进行水团分析 ,以四边形水团定量分析方法得到各水团在海区内的分布状况 ,同时分析了温度、盐度、密度和溶解氧的分布 ,并对在相同深度层次上的南海水和黑潮水性质进行了比较。观测海域的水团分为表层水团 (SW ) ,次表层水团 (SSW ) ,中层水团 (IW )和深层水团 (DW ) ,分别处于 0～ 5 0m ,5 0～ 3 0 0m ,40 0～ 10 0 0m ,10 0 0m以深。黑潮水进入南海 ,但是势力较弱 ,未能越过 119.5°E深入南海。     

2008年夏季南海北部海区生物光学特性的垂向变化特征

Vertical variability in the bio-optical properties of seawater in the northern South China Sea(NSCS) including inherent optical properties(IOPs) and chlorophyll a concentration(Chl) were studied on the basis of in situ data collected in summer 2008 using an absorption/attenuation spectrophotometer. An empirical model was developed to estimate Chl profiles based on the absorption line height at long wavelengths, with a relative root mean square error of 37.03%. Bio-optical properties exhibited large horizontal and vertical spatial variability. As influenced by coastal upwelling and the Zhujiang River(Pearl River) discharge, both IOPs and Chl exhibited high values in the surface waters of the inner shelf, which tended to decrease with distance offshore. Subsurface maximum layers of IOPs and Chl were observed in the middle and outer shelf regions, along with significantly higher values of attenuation coefficients beneath this layer that rapidly increased towards the bottom. In the open ocean, both IOPs and Chl exhibited consistent variability, with the subsurface maximum layer typically located at34–84 m. Phytoplankton were found to be one of the major components in determining the vertical variability of bio-optical properties, with their vertical dynamics influenced by both physical forcing and light attenuation effects. The depth of the subsurface maximum layer was found to be closely related to the fluctuation of the oceanic thermocline and the depth of the euphotic zone, which also affected the total integrated biomass of the upper ocean. Typically high values of attenuation coefficients observed in the bottom waters of the continental shelf reflected the transport of particulate matter over the bottom boundary layer. Our results reveal large spatial differences in bio-optical profiles in response to complex marine ecodynamics in the NSCS. From the perspective of marine research, high-resolution optical measurements are clearly advantageous over conventional bottle sampling.     

Water masses in the northern South China Sea

Using the fuzzy clustering as the principal method, eight water masses in the northern South China Sea (NSCS) are distinguished. They are Alongshore Diluted Water Mass (F), Nearshore Mixed Water Mass (M), Warm Surface Water Mass(WS), Surface Water Mass(S), Surface-Subsurface Mixed Water Mass(SU), Subsurface Water Mass (U), Subsurface-Intermediate Water Mass (UI) and Intermediate Water Mass (1). A synthertic study is made on the formations, basic properties and modified characters of each water mass and the regularities of their disributions and growth and decline variations . They may be classified into three types; the type of runoff-diluted water (F). the type of shallow sea-modified water (M, WS. S. and SU) and the type of deep sea-oceanic water (U, UI, and I).     

夏季南海北部微型浮游动物群落

根据2014年8月至9月于珠江口至南海中部断面(18°00'~22°00'N,114°00'~116°00'E)的南海北部海域进行采样调查,并进行了微型浮游动物群落分析。共发现微型浮游动物142种,隶属于2门44属,其中砂壳纤毛虫28属78种,占所有发现物种数的54.93%;寡毛类纤毛虫14属59种,占所有发现物种数的41.55%。优势类群为:拟卡金斯急游虫(Strombidium paracalkinsi)、具沟急游虫(Strombidium sulcatum)、维尔伯特急游虫(Strombidium wilberti)和无节幼体(nauplii)。调查区微型浮游动物的丰度介于11.43~959.35 ind/L之间,平均值为264.99 ind/L。微型浮游动物垂直分布总体特点是密集区位于50 m水层,50 m水层之下丰度逐渐减少。表层微型浮游动物丰度高值区位于J5-I1站位之间。断面的香农-威纳指数范围在0.92~4.18之间,平均值为2.77;均匀度指数在0.63~1之间,平均值为0.87。应用典范对应分析(CCA)发现温度和盐度是影响微型浮游动物群落的重要因素。通过对连续追踪站位的调查发现,上层水体微型浮游动物群落丰度随着时间而发生一定的变化,下层水体相对较平缓。微型浮游动物昼夜的垂直丰度变化与叶绿素浓度昼夜变化大致相符。     

关于南海北部上层水团的分类及三维分布的研究

Using the fuzzy cluster analysis and the temperature-salinity(T-S) similarity number analysis of cruise conductivity-temperature-depth(CTD) data in the upper layer(0–300 m) of the northern South China Sea(NSCS), we classify the upper layer water of the NSCS into six water masses: diluted water(D), surface water(SS),the SCS subsurface water mass(U_S), the Pacific Ocean subsurface water mass(U_P), surface-subsurface mixed water(SU) and subsurface-intermediate mixed water(UI). A new stacked stereogram is used to illustrate the water mass distribution, and to examine the source and the distribution of U_P, combining with the sea surface height data and geostrophic current field. The results show that water mass U_P exists in all four seasons with the maximum range in spring and the minimum range in summer. In spring and winter, the U_P intrudes into the Luzon Strait and the southwest of Taiwan Island via the northern Luzon Strait in the form of nonlinear Rossby eddies, and forms a high temperature and high salinity zone east of the Dongsha Islands. In summer, the U_P is sporadically distributed in the study area. In autumn, the U_P is located in the upper 200 m layer east of Hainan Island.     

Application of method of fuzzy sets to the analysis of water masses in the northern South China Sea

Some methods of fuzzy sels are applied to the analysis of water masses in the north area of the South China Sea. In distinguishing water masses with the fuzzy clustering method, the authors propose a fuzzy similar relation based on Euclidean distance, and suggest a method for determining the number of water masses by the F-test, and further adjust rationally the boundaries of water masses and the membership relation of samples by the elastic classification method. Eight water masses are distinguished in the area, i.e., Nearshore Diluted Water F, Nearshore Mixed Water M, Warm Surface Water WS, Surface Water S, Surface-Subsurface Mixed Water SU, Subsurface Water U, Subsurface-Intermediate Mixed Water UI and Intermediate Water I. These point-sets of various water masseson the (?)-S diagram may be summed up in three types, that is, the deformed elliptical convexpoint-set, the half-boundless convex point-set and the point-set with single-side concave. For them, we have proposed methods of making their member     

南海北部冬、夏季浮游群落呼吸率

Plankton respiration is an important part of the carbon cycle and significantly affects the balance of autotrophic assimilation and heterotrophic production in oceanic ecosystems. In the present study, respiration rates of the euphotic zone plankton community(CR_(eu)), size fractionated chlorophyll a concentration(Chl a), bacterial abundance(BAC), and dissolved oxygen concentration(DO) were investigated during winter and summer in the northern South China Sea(n SCS). The results show that there were obvious spatial and temporal variations in CR_(eu) in the n SCS(ranging from 0.03 to 1.10 μmol/(L·h)), CR_(eu) in winter((0.53±0.27) μmol/(L·h)) was two times higher than that in summer((0.26±0.20) μmol/(L·h)), and decreased gradually from the coastal zone to the open sea. The distribution of CR_(eu) was affected by coupled physical-chemical-biological processes, driven by monsoon events. The results also show that CR_(eu) was positively correlated with Chl a, BAC, and DO, and that BAC contributed the highest CR_(eu) variability. Furthermore, the results of the stepwise multiple linear regression suggest that bacteria and phytoplankton were the dominant factors in determining CR_(eu)(R~2 = 0.82, p0.05) in the n SCS. Based on this relationship, we estimated the integrated water column respiration rate(CRint) within 100 m of the investigated area, and found that the relationship between the biomass of the plankton community and respiration may be nonlinear in the water column.     

2014年夏季南海北部浮游植物群落结构

2014年8月20日-9月6日对南海北部(18°~22°N,114°~116°E)的11个站位进行了浮游植物群落结构的调查,其中2个站位为时间连续站。共鉴定出浮游植物4门68属229种(包括变种、变型及未定种),其中硅藻门43属147种,甲藻门20属75种。浮游植物平均细胞丰度为16.318×103 cells/L,硅藻的平均细胞丰度为14.653×103 cells/L,占总丰度的89.80%,硅藻的分布决定了浮游植物的分布。近岸冲淡水含有丰富的营养盐,因此近岸海域的细胞丰度高于大洋海域,垂直分布表现出先增加后降低的趋势。本次调查的优势种为铁氏束毛藻(Trichodesmium thiebautii)、中肋骨条藻(Skeletonema costatum)、拟脆杆藻(Fragilariopsis sp.)、短孢角毛藻(Chaetoceros brevis)、菱形海线藻(Thalassionema nitzschioides)、柔弱伪菱形藻(Pseudo-nitzschia delicatissima)、尖刺伪菱形藻(Pseudo-nitzschia pungens)、扁面角毛藻(Chaetoceros compressus)、洛氏角毛藻(Chaetoceros lorenzianus)以及海洋角毛藻(Chaetoceros pelagicus),各优势种的分布趋势相似,呈现出近岸高于外海的趋势。Shannon-Weiner多样性指数与Pielou均匀度指数的平均值分别为2.37和0.56。浮游植物昼夜垂直变化明显。典范对应分析结果显示浮游植物空间分布主要受总氮盐、硅酸盐、微型浮游动物与盐度的影响。根据细胞丰度进行的站位的聚类分析显示浮游植物群落明显可划分为近岸群聚与大洋群聚。     

Three-dimensional circulation in northern South China Sea during early summer of 2015

Using the hydrographic data obtained during two nearly simultaneous surveys in June 2015, we carried out semidiagnostic calculations with the help of a finite element model and a modified inverse method, to study the circulation in the northern South China Sea(NSCS) during the early summer of 2015. A number of new circulation features were found.(1) In most of the observation region, a large, basin-scale anticyclonic gyre appeared south of the 50-m isobath, which contained anticyclonic eddies. One anticyclonic eddy existed from the sea surface to 50-m depth, whose center showed no tilt, while the center of another eddy tilted eastward from the sea surface to 500-m depth. In the eastern part of the observation region, which is west of the Dongsha Islands, there was a sub-basinscale cyclonic gyre containing a cyclonic eddy whose center tilted southward from the sea surface to 200-m depth.(2) There was a cross-continental slope current(CCSC) in the area southwest of the Dongsha Islands. Its volume transport was about 2.0×10~6 m~3/s.(3) From the estimated order of magnitude of the stream function equation, the joint effect term of the baroclinity and relief(JEBAR) and β-effect term are two important dynamic mechanisms affecting the variation of the circulation in the NSCS.(4) The JEBAR, as a transport-generating term, resulted in the dynamic mechanism determining the pattern of the depth-averaged flow across the contours of potential vorticity fH~(–1). Furthermore, we show that the negative values of the JEBAR were the most dominant dynamic mechanism, causing the CCSC southwest of the Dongsha Islands to deflect from the isobaths and veer toward the deep water. The CCSC around the Dongsha Islands was located further southwest during the early summer of2015 than during the fall of 2005(revealed by a published study), which suggests that the location of the CCSC around the Dongsha Islands may vary with season.     

南海北部冬、夏季海表浮游植物光合作用速率对光强的响应特征

本文通过南海北部冬、夏季航次的现场观测,研究了海表浮游植物光合作用速率对光强的响应特征(P-E曲线)。结果表明南海北部浮游植物P-E曲线存在明显的季节变化。在冬季,P-E曲线呈现高P_mB、高α、高β的特征,这表明冬季浮游植物在低光照环境中光合作用速率增加迅速,其最大光合作用速率较高但容易受到光抑制。与冬季相反,夏季P-E曲线呈现低P_mB、低α、低β的特征,浮游植物受光抑制影响小,但最大光合作用速率低于冬季。水温和粒级结构等指标与P-E参数存在显著相关,这意味着环境和群落的季节变化可能对光合作用特性有一定影响。通过P-E参数模拟得到真光层内光合作用速率,模拟值与现场结果之间呈明显的线性相关但存在高估。此研究有助于认识南海浮游植物光合作用特征,并为初级生产力模型研究提供依据。     

2009 年夏季南海北部的浮游植物群落

根据2009 年8 月份对南海北部(18°～22°N, 110°～117°E)水域22 个采水站位的调查, 分析夏季调查区浮游植物的群落结构特征。通过Uterm?hl 方法共鉴定出浮游植物5 门60 属109 种(不包括未定种),群落组成以硅藻为主, 其次是甲藻。浮游植物生态类群以广温广布型种为主, 调查区的优势种为柔弱伪菱形藻Pseudo-nitzschia delicatissma, 菱形海线藻Thalassionema nitzschioides, 颗粒直链藻Melosiragrannulata, 尖刺伪菱形藻Pseudo-nitzschia pungens, 矮小短棘藻Detonula pumila, 原多甲藻Protoperidinium sp., 以及冰河拟星杆藻Asterionopsis glacialis。调查区细胞丰度介于0.009×10³个/L到249.930×10³个/L, 平均8.197×10³个/L。南海北部表层浮游植物细胞丰度由近岸向外海逐渐降低,高值区位于珠江口附近以及南部水域, 甲藻在广东沿岸附近出现高值。调查区浮游植物丰度在垂直方向随着水深的增加而递减。Shannon-Wiener 多样性指数和Pielou 均匀度指数在珠江口南部和广东沿岸站位出现低值区, 群落结构稳定性较差。