白令海和楚科奇海表层沉积硅藻分布特征

对我国第二次和第三次北极科学考察在白令海和楚科奇海获取的部分表层沉积物样品进行了详细的硅藻分析,旨在了解白令海和楚科奇海表层沉积硅藻的主要分布情况。研究发现海冰对北极硅藻有着显著的影响,在最小冰边缘线以北海域,由于常年被海冰覆盖,表层沉积物中的硅藻数量极少甚至缺失,而在此范围以南海域,硅藻含量则甚为丰富。白令海和楚科奇海表层沉积物中最主要的硅藻种类及组合有：角毛藻休眠孢子(Chaetoceros resting spores),海冰硅藻组合(以Fragilariopsis oceanica和Fragilariopsis cylindrus为代表),极地硅藻组合(优势种有Bacterosira bathyomphla,Thalassiosira antarctic v. borealis及其休眠孢子),沿岸底栖硅藻组合(主要有Paralia sulcata和Delpheneis surirella),诺氏海链藻(Thalassiosira nordenskioeldii)和塞米新细齿藻(Neodenticula seminae)等。上述硅藻种类及组合具有显著的空间分布差异性,并与现代海洋环境因素密切相关,因此对于白令海和楚科奇海古海洋环境研究具有重要意义。     

Coordinated changes of sea ice over the Beaufort and Chukchi seas: regional and seasonal perspectives

One outstanding feature of the recent Arctic climate is the contrast of the changes of sea ice concentration and thickness between the Beaufort Sea and the Chukchi Sea. Since the Arctic Oscillation (AO) plays a critical role in driving Arctic sea ice changes and the Beaufort and Chukchi seas have been hypothesized as a region in which sea ice anomalies originate, we employed a coupled sea ice-ocean model and carried out simulations forced by the AO signal to examine sea ice changes in these regions, focusing on seasonality. With the AO phase transition from negative to positive, anticyclonic windstress weakens broadly in both winter and summer; however, the surface air temperature response shows remarkable seasonal dependence. Positive temperature anomalies spread over the entire domain in winter, while negative anomalies occur in the shelf seas in summer, although positive anomalies remain in the deep-water portion. The simulated sea ice concentration resembles the observed concentration. The strong seasonality of sea ice concentration changes suggests that accumulation of sea ice concentration in the Beaufort Sea and reduction in the Chukchi Sea are mainly produced in summer. Changes of ice thickness are robust through the seasonal cycle. Generally, sea ice dynamics play a critical role in creating the anomalous sea ice pattern and sea ice thermodynamics partially compensate the dynamically-driven changes. However, considerable seasonal differences occur.     

1999年夏季中国首次北极考察区水团特征

依据 1 999年 7月至 9月中国首次北极考察队在白令海、楚科奇海和南加拿大海盆的现场调查资料 ,本文分析了三个海区的水团特征 :( 1 )白令海水团主要由季节变化显著的白令海上层水团和中层水团以及深层水团组成 ;( 2 )楚科奇海水文特征受融结冰过程影响较大 ,1 999年7月和 8月差异较大 ,其水团主要为浅海变性水团 ,包括两个次级水团 ,楚科奇海夏季水和来自北太平洋以及北冰洋变性的外海入侵水 ;( 3)南加拿大海盆的水团主要由受融结冰过程影响的表层水团、源于太平洋水的次表层水、源自北大西洋的中层水团和深层水团组成     

2003年与1999年楚科奇海海冰的差异及其发生原因

我国在1999年和2003年进行了两次北极考察,这两年海冰的冰情差别很大,分别对应冰情较重和较轻的年份。本文利用卫星遥感资料对1999年和2003年的海冰分布状况及其差异进行了全面的分析,并利用气温和风场资料深入研究形成这种差异的动力学原因。结果表明, 2003年的海冰冰情与1999年相比要轻很多,海冰面积在春季融冰季节和秋季冻结季节显著减小。2003年春季,来自白令海的海水提早半个月进入楚科奇海,导致海冰大范围融化。但是,到了夏季,海冰的面积减少过程停滞下来。而秋季楚科奇海封冻过程比1999年晚半个月。以上这些特征形成了2003年与1999年海冰的显著差异。研究结果表明, 2003年春季和秋季的气温比1999年要明显增高,最大月平均温差接近18°C,显著的高温为海冰融化的加剧和冻结的推迟提供了热量。直接影响海冰分布的是海面风场,两年风场的差异产生了来自白令海的太平洋入流的差异,对春季海冰融化的提前、夏季入流的减弱和秋季冻结过程的推迟起到关键的作用。季节性气象要素的年际差异可以归因于整个北极的AO系统变化, 2003年AO指数是正值, 1999年为负值,成为楚科奇海局地海冰变化的气候背景。     

影响北极地区迅速变化的一些关键过程研究

最近研究证明 ,近半个世纪来 ,北极地区正在发生迅速变化。部分地区温度上升了 2- 3°C ,北冰洋海冰退缩 5 %,中心地区海冰厚度变薄 ,海面压力降低 ,中上层水淡化和变暖 ,吸收CO2 能力增加 ,臭氧耗损和紫外线辐射增强。中国于 1 999年开展了“中国首次北极科学考察” ,在楚科奇海、加拿大海盆、白令海以及临近海域开展了海冰气相互作用的多学科综合考察 ,对北极的区域特征及其在全球变化中的作用研究获得一些新的认识。观测到加拿大海盆中层水持续增暖的现象 ,揭示了西北冰洋与白令海水体交换的途径和次表层暖水结构 ,发现了加拿大海盆是北冰洋河水的主要储存区。利用联合冰站观测数据 ,模拟了北冰洋夏季大气边界层结构和下垫面能量平衡的变化特征 ,定量给出了北冰洋夏季海 /气和冰 /气之间湍流通量和边界层参数的差异。海 /气CO2 的通量观测表明 ,考察区的大部分海域均为大气CO2 汇区 ;西北冰洋海冰区具有较高的生物泵运转效率 ,楚科奇海陆架是一个高效的有机碳“汇”区 ,寒冷水体中微生物活动并未受到明显抑制。沉积物的地球化学过程研究表明 ,海底表层沉积物中碘含量存在着由低纬度到高纬度增加趋势 ,北极地区可能是碘的汇区 ,碘可作为极区古海洋中的地球化学元素变化的重要指标。楚科奇海、白令海     

楚科奇海和白令海的海洋低温微生物调查

在 1 999年北极夏季期间对楚科奇海和白令海的海洋低温微生物进行了调查。在楚科奇海 ,海洋细菌和海洋真菌的检出率分别为 1 0 0 %和 >94% ,其相应的总量一般分别为 >1 0 3 cells/cm3 和 1 0 1— 1 0 3 cells/cm3 ;在大多数站位 ,海洋细菌的总量通常都高于海洋真菌的总量 ;从表层至 1 0 m或 3 0 m深层的海水区域 ,分布有丰富的海洋微生物。调查结果还显示 ,不同站位间的海洋微生物总量存在明显差异 ,海冰的融化和海水中的盐度可能是影响这一海区海洋微生物总量的重要因素。在白令海 ,海洋细菌的检出率为 1 0 0 % ,其总量一般在 1 0 2 — 1 0 3 cells/cm3 ;海洋真菌的检出率 >84% ,其总量一般也在 1 0 2 — 1 0 3 cells/cm3 。白令海不同站位间的海洋微生物总量也存在较大的差异。调查结果证实在楚科奇海和白令海的确存在大量的低温海洋微生物 ,在所研究的海洋细菌中 ,分别有 81 %的楚科奇海细菌和 88.9%的白令海细菌能够在低温条件下 (<1 0℃ )良好生长 ,而且有部分菌株能够在低温条件下分解利用淀粉或纤维素等多糖物质以满足自身生长的营养需求。这些海洋低温菌株为进一步开发利用这些海域的海洋微生物资源提供了充足的材料     

楚科奇海和白令海浮游植物的种类组成与分布

根据 1 999年 7月至 8月我国首次北极科学考察期间“雪龙”号考察船在楚科奇海 ( 66°0 .3′N75°1 8.6′N ,1 5 3°36.5′W 1 74°5 9.5′W )和白令海 ( 5 5°5 9.8′N66°0 .3′N ,1 73°2 1 .1′E1 75°5 3.9′W)采集的 5 1份网采样品和 2 4份水采样品 ,鉴定浮游植物 3个门类 38属 1 2 1种 (含变种和变型 ) ,都是真核藻类。其中楚科奇海有 33属 1 0 3种 ,白令海有 2 5属 71种 ,两海区共有种 49种。这些种类可分为 4个生态类群 :( 1 )北极类群 ;( 2 )北极、亚北极北方类群 ;( 3)北方温带类群 ;( 4 )世界性广温类群等。主要优势种有楚科奇海的格鲁菱形藻 (Nitzschiagrunowii)、诺登海链藻(Thalassiosiranordenskioldi)和聚生角毛藻 (Chaetocerossocialis)等和白令海的西氏细齿状藻(Denticulaseminae)、柔弱菱形藻 (Nitzschiadilicatissima)、成列菱形藻 (N .seriata)和长海毛藻(Thalassiothrixlongissima)等。楚克奇海浮游植物的平均丰度 ( 8.32× 1 0 7个 /m3)远高于白令海( 1 .5 8× 1 0 6个 /m3)。文中还讨论了调查区浮游植物的分布特点及其与环境的关系。     

A coupled multi-category sea ice model and POM for Baffin Bay and the Labrador Sea

An overview of the seasonal variation of sea-ice cover in Baffin Bay and the Labrador Sea is given.A coupled ice-ocean model,CECOM,has been developed to study the seasonal variation and associated ice-ocean processes.The sea-ice component of the model is a multi-category ice model in which mean concentration and thickness are expressed in terms of a thickness distribution function.Ten categories of ice thickness are specified in the model.Sea ice is coupled dynamically and thermo-dynamically to the Princeton Ocean Model.Selected results from the model including the seasonal variation of sea ice in Baffin Bay,the North Water polynya and ice growth and melt over the Labrador Shelf are presented.     

Oxygen isotopic composition and its application to the study of tracing oceanographical process in Bering Sea and Chukchi Sea

In this paper, the 18 O distribution of surface water from the central sea areas of the Bering Sea and the Chukchi Sea was studied. The δ 18 O value of surface water from the Bering Sea is averagely -0.5‰; the δ 18 O contents of the Chukchi Sea are distributionally lower in northeast and higher in southwest; the δ 18 O value at the margin of Canadian Basin is -2.8‰, and averagely -0.8‰ in the southern area of the Chukchi Sea. The δ 18 O vertical distribution in some deep water stations from the Chukchi Sea and the Bering Sea is also studied. In the southern margin of Canadian Basin, the δ 18 O value is -2‰ -3‰ for surface layer and rises to 0 at 100 m depth layer. In the Bering Sea, the δ 18 O is about -0.5‰ for surface layer and increases to 0 at the depth of 300 m. The NO tracer can reflect obviously three water masses vertically distributed in the central Bering Sea: the upper Bering water mass, the middle Bering water mass and the deep Pacific water mass. The distributive ranges of NO and temperature for the various water masses are T<7℃, NO>780 μmol/dm 3 and T≥7℃, NO>650 μmol/dm 3 for upper Bering water mass, T<4℃, 550相似文献   

白令海和楚科奇海水文特征和水团结构的初步分析

根据我国首次北极科学考察所获 CTD资料 ,分析了白令海和楚科奇海的水文特征和水团结构。研究表明 :(1 )该两海域温、盐度的分布有着明显的区域性差异。楚科奇海的温、盐度普遍低于白令海。 (2 )夏季 ,白令海大部分水域温度垂直分布的突出特点是 :在 2 0 m和 2 5 0 m间存在温度低于 3°C的中层冷水。 (3 )在楚科奇海北纬 70°以北海域 ,不论是水温或盐度皆明显减小 ,从而在此区域形成强的温、盐度锋带。 (4)在白令海存在三种水团 ,而楚科奇海的水团则大致分为两类     

北极海冰与大气环流耦合主模态的时空特征分析

对1979—2009年月平均的CFSR（The Climate Forecast System Reanalysis）海冰密集度（SIC）和海平面气压（SLP）资料进行多变量经验正交函数分解（MV—EOF）,得出耦合主模态,并通过对温度、位势高度和风场的回归分析,进一步探寻海冰与大气环流的关系,第一模态SLP的特征为北极涛动（AO）,SIC呈离散的正负中心分布但大体为东西反位相,AO正位相时,喀拉海、拉普捷夫海、东西伯利亚海和鄂霍次克海海冰减少,巴芬湾、波弗特海、楚科奇海和白令海海冰增加。耦合第二模态的SLP呈偶极子分布,负、正异常中心在巴伦支海和波弗特海,SIC在巴伦支海,弗拉姆海峡,格陵兰海,拉布拉多海和白令海,鄂霍次克海地区有正异常,在喀拉海、拉普捷夫海、东西伯利亚海、楚科齐海和波弗特海为负异常。耦合第三模态SLP在冰岛地区存在负异常中心,在拉普捷夫海地区有正异常中心,SIC在巴伦支海北部、弗拉姆海峡、格陵兰海为负异常,其余地区全为正异常。 对SLP和SIC分别进行EOF分解,并与耦合模态进行比较,SLP的EOF主模态的时空分布与耦合模态中SLP的时空分布十分相似,SIC的EOF模态的时空分布则与耦合模态中SIC的时空分布有较大差别,说明耦合模态对SIC的分布影响较大,即大气环流对海冰分布的影响为主要的过程,海冰对大尺度的大气环流的模态的影响不明显。     

Abundance,biomass and composition of spring ice algal and phytoplankton communities of the Laptev Sea(Arctic)

<正> Abundance,biomass and composition of the ice algal and phytoplank-ton communities were investigated in the southeastern Laptev Sea in spring 1999.Diatoms dominated the algal communities and pennate diatoms dominated the dia-tom population.12 dominant algal species occurred within sea ice and underlyingwater column,including Fragilariopsis oceanica,F.cylindrus,Nitzschiafrigida,N.promare,Achnanthes taeniata,Nitzschia neofrigida,Naviculapelagica,N.vanhoef fenii,N.septentrionalis,Melosira arctica,Clindrothecaclosterium and Pyrarnimonas sp.The algal abundance of bottom 10 cm sea icevaried between 14.6 and 1562.2×10~4 ceils l~(-1)with an average of 639.0×10~4cells l~(-1),and the algal biomass ranged from 7.89 to 2093.5μg C l~(-1)with an av-erage of 886.9μg C l~(-1),which were generally one order of magnitude higherthan those of sub-bottom ice and two orders of magnitude higher than those ofunderlying surface water.The integrated algal abundance and biomass of lower-most 20 cm ice column were averagely 7.7 and 12.2 times as those of upper 20 mwater column,respectively,suggesting that the ice algae might play an importantrole in maintaining the coastal marine ecosystem before the thawing of sea ice.Icealgae influenced the phytoplankton community of the underlying water column.However,the“seeding”of ice algae for phytoplankton bloom was negligible be-cause of the iow phytoplankton biomass within the underlying water column.     

北极拉普捷夫海春季冰藻和浮游植物群落结构及生物量分析

对1999年春季采集于北极拉普捷夫海东南部的冰藻和冰下浮游植物群落的种类组成进行了分析,并对丰度和生物量进行了统计和对比。藻种以硅藻占绝对优势,其中又以羽纹硅藻为主。优势种集中,主要包括海洋拟脆杆藻(Fragilariopsisoceanica)、圆柱拟脆杆藻(F.cylindrus)、寒冷菱形藻(Nitzschiafrigida)、普罗马勒菱形藻(N. promare)、带纹曲壳藻(Ach nanthestaeniata)、新寒冷菱形藻(Nitzschianeofrigida)、大洋舟形藻(Naviculapelagica)、范氏舟形藻(N. vanhoeffenii)、北极直链藻(Melosiraarctica)、北方舟形藻(N. septentrionalis)、新月细柱藻(Clindrothecaclosterium)和绿藻门的塔形藻(Pyramimonassp. )。微藻主要集中在冰底10cm,丰度为14. 6-1562. 2×104 cells·L-1,平均为639. 0×104 cells·L-1;生物量为7. 89-2093. 5μgC·L-1,平均为886. 9μgC·L-1,总体上比次冰底高1个数量级,比冰下表层水柱高2个数量级。冰底20cm冰柱的累计丰度和生物量平均分别为冰下20m水柱累计量的7. 7和12. 2倍,显示冰藻在春季海冰融化前在近岸生态系统中的重要作用。尽管各站位冰底和冰下表层水柱藻类群落的相似性普遍不高,但整个调查海域冰底和冰下水柱优势种极为相似,春季期间冰藻对冰下浮游植物群落的影响明显。由于     

The role of Pacific water in the dramatic retreat of arctic sea ice during summer 2007

A model study is conducted to examine the role of Pacific water in the dramatic retreat of arctic sea ice during summer 2007.The model generally agrees with the observations in showing considerable seasonal and interannual variability of the Pacific water inflow at Bering Strait in response to changes in atmospheric circulation. During summer 2007 anomalously strong southerly winds over the Pacific sector of the Arctic Ocean strengthen the ocean circulation and bring more Pacific water into the Arctic than the recent(2000-2006) average.The simulated summer(3 months) 2007 mean Pacific water inflow at Bering Strait is 1.2 Sv,which is the highest in the past three decades of the simulation and is 20%higher than the recent average.Particularly ,the Pacific water inflow in September 2007 is about 0.5 Sv or 50%above the 2000-2006 average.The strengthened warm Pacific water inflow carries an additional 1.0×10~(20) Joules of heat into the Arctic,enough to melt an additional 0.5 m of ice over the whole Chukchi Sea.In the model the extra summer oceanic heat brought in by the Pacific water mainly stays in the Chukchi and Beaufort region,contributing to the warming of surface waters in that region.The heat is in constant contact with the ice cover in the region in July through September.Thus the Pacific water plays a role in ice melting in the Chukchi and Beaufort region all summer long in 2007,likely contributing to up to 0.5 m per month additional ice melting in some area of that region .     

Primary production of the northern Barents Sea

The majority of the arctic waters are only seasonally ice covered; the northern Barents Sea, where freezing starts at 80 to 81°N in September, is one such area. In March, the ice cover reaches its greatest extension (74-75°N). Melting is particularly rapid in June and July, and by August the Barents Sea may be ice free. The pelagic productive season is rather short, 3 to 3.5 months in the northern part of the Barents Sea (north of the Polar Front, 75°N), and is able to sustain an open water production during only half of this time when a substantial part of the area is free of ice. Ice algal production starts in March and terminates during the rapid melting season in June and July, thus equalling the pelagic production season in duration.
This paper presents the first in situ measurements of both pelagic and ice-related production in the northern Barents Sea: pelagic production in summer after melting has started and more open water has become accessible, and ice production in spring before the ice cover melts. Judged by the developmental stage of the plankton populations, the northern Barents Sea consists of several sub-areas with different phytoplankton situations. Estimates of both daily and annual carbon production have been based on in situ measurements. Although there are few sampling stations (6 phytoplankton stations and 8 ice-algae stations), the measurements represent both pelagic bloom and non-bloom conditions and ice algal day and night production. The annual production in ice was estimated to 5.3 g Cm^-2, compared to the pelagic production of 25 to 30 g Cm^-2 south of Kvitøya and 12 to 15 g Cm^-2 further north. According to these estimates ice production thus constitutes 16% to 22% of the total primary production of the northern Barents Sea, depending on the extent of ice-free areas.     

The significance of water column nitrification in the southeastern Bering Sea

Nitrate is considered the nutrient that limits new primary production in the southeastern Bering Sea shelf.Nitrate regenerated through biological nitrification has the potential to significantly support primary production as well.Here we use measurements of the specific rate of water column nitrification in a 1-D ecosystem model to quantify the resupply of nitrate from nitrification in the middle shelf of the southeastern Bering Sea.Model sensitivity studies reveal nitrification rate is an important control on the dominant phytoplankton functional type,and the amount of nitrate in summer bottom waters and in the winter water column.Evaluation of nitrification using the model supports the hypothesis that increases in late-summer nitrate concentrations observed in the southeastern Bering Sea bottom waters are due to nitrification.Model results for nitrate replenishment exceed previously estimated rates of 20-30%based on observations.The results of this study indicate that nitrification,potentially the source of up to～38%of the springtime water column nitrate,could support～24%of the annual primary production.     

北极现代沉积物中正构烷烃的分子组合特征及其与不同纬度的海域对比

北极海域楚科奇海和白令海表层沉积物的正构烷烃气相色谱图呈双峰群分布,楚科奇海正构烷烃分子组合特征高碳数峰群MH(主峰碳)在nC25-nC33、低碳数峰群MH在nC16-nC20范围;白令海高碳数峰群MH在nC25-nC27、低碳数峰群MH在nC17-nC22范围。两海域的OEP(奇偶优势指数)各为0.9-3.81、0.409-3.26;C-23/C+24比值为0.18-1.53、0.40-2.57之间;TABHC(陆/水生类脂物)比值在0.57-11.35、0.32-5.97之间。根据分子组合特征表明楚科奇海的陆源物质输入要比白令海大,而白令海的表层生产力又比楚科奇海高。本文将北极海域现代沉积过程中的正构烷烃分子组合特征与南极进行对比,同时又将高纬度海域与低纬度海域渤海、黄海、东海和南海进行对比,研究发现由高纬度北极到低纬度海域的陆源输入特征依次减弱,而海洋生物自身起源特征加强。不同纬度海域的表层沉积物中正构烷烃呈现出不同的分子组合差异,受到现代海洋沉积过程中物质来源、环境、气候诸多因素的影响。     

Phytoplankton in the south-western Kara Sea: composition and distribution

The taxonomic composition and spatial distribution of pelagic algae were studied in the south-western Kara Sea in August-September 1981. In the north-western and easternmost regions of the study area the phytoplankton community, dominated by neritic diatoms and autotrophic dinoflagellates, was at the late spring bloom stage of the seasonal succession. In the central deep-water zone of the sea, there was a predominance of heterotrophic dinoflagellates from the genera Protoperidinium and Dinophysis , and the autotrophic compartment of the algal community was clearly in a stage of decline. The distribution of the phytoplankton assemblages followed closely the major routes of receding marginal ice zones. Three stages of the seasonal succession were established for the area of interest: (1) early spring (ice edge) bloom of arcto-boreal neritic diatoms; (2) late spring bloom of neritic diatoms and autotrophic dinoflagellates, fuelled by continental run-off; and (3) summer minimum with a predominance of heterotrophic dinoflagellates, followed by autumnal decline of the phytoplankton community.     

白令海和楚科奇海陆架区的生源物质埋藏通量研究

楚科奇海和白令海通过白令海峡相连,是气候变化研究的关键区域。利用210Pb过剩法开展两个海域沉积过程和生源物质的埋藏通量研究。研究发现,白令海陆架区沉积柱样(NB22)受到生物扰动影响,楚科奇海沉积物柱样(R17)所受生物扰动很小。通过建立模型,获得楚科奇海陆架区的沉积速率为0.6±0.1 mm·a~(-1),白令海陆架区的沉积速率为2.1±0.7 mm·a~(-1)。忽略沉积过程,白令海陆架区由生物扰动引起的混合因子为1.38±0.92 cm2·a~(-1);考虑沉积过程,则混合因子为0.65±0.95 cm2·a~(-1)。白令海的有机碳、生源硅、Ca CO3的埋藏通量分别为:6.85 mmol C·m-2·d-1、37.7 mmol Si·m-2·d-1、3.15 mmol C·m-2·d-1;楚科奇海的有机碳、生源硅、Ca CO3的埋藏通量分别为:5.71 mmol C·m-2·d-1、9.78 mmol Si·m-2·d-1、3.08 mmol C·m-2·d-1。楚科奇海陆架区具有高效的垂直输运的海洋生物泵,白令海陆架区海洋生物泵可能存在较强的水平输运过程。海洋沉积物中210Pb信号不仅可以定量沉积速率和埋藏通量,也在一定程度上反映海洋底栖生物的扰动强度。     

楚科奇海浮冰区夏季短期颗粒有机物通量及其主要组分

中国首次北极科学考察期间 ,于 8月 2 0- 2 3日在楚科奇海浮冰区联合冰站实施了为期 4天的短期颗粒有机物通量研究。结果显示真光层的颗粒有机碳通量为 1 .582mgCm- 2 day- 1 ,2 2 0m深层为 1 .339mgCm- 2 day- 1 ,而相应的沉降颗粒物总通量分别高达 8.788和 1 0 .30 3mgm- 2 day- 1 。显示北极浮冰区的夏季融冰季节后期 ,颗粒有机碳通量的水平较低。与颗粒有机碳通量水平相似 ,生源硅和活性磷的通量水平也较低。对硅藻通量组份的分析表明 ,真光层沉降硅藻的优势种为Nitzschiacf.seriata、Naviculaglacialis和Melosirasp .,而 2 2 0m层则Lepto cylindrussp .占绝对优势 ,其丰度数量百分比均超过 70 %。硅藻碳通量的绝对值较低 ,为0 .1 0 7- 0 .1 1 3mgCm- 2 day- 1 。然而 ,真光层大型桡足类的碳估算值高达 1 0 8.67mgCm- 2day- 1 ,占浮游动物总碳量的 95 .3 % ,大型浮游动物的表观碳通量高于浮游植物碳通量 2- 3个数量级 ,显示楚科奇海夏季融冰期高浮游动物碳量、低浮游植物碳量的特点。但浮游动物表观碳量高的主要原因与浮游动物的昼夜垂直运动有关 ,却并非是实际向深层海洋传输的碳量