白令海北部陆坡BR07孔年龄框架重建

通过对比白令海BR07孔与B5-4孔硅藻百分含量、颜色反射率等参数结果,综合建立了BR07孔年龄框架。根据该重建年龄结果,BR07孔年龄约为11.3~1.9 ka,平均沉积速率约为28.5 cm/ka,略低于B5-4孔。基于圆柱拟脆杆藻与塞米新细齿藻比值Fragilariopsis cylindrus含量/（Fragilariopsis cylindrus含量+Neodenticula seminae含量）重建的近万年来白令海海冰变化历史,记录到该区域末次冰消期以来包括新仙女木事件在内的3次冷事件以及1次暖事件,其中新仙女木事件约发生于距今11.3~10.7 ka,与格陵兰冰心记录对应值距今12.9~11.6 ka基本相近,这进一步佐证了该重建年龄比原始的全样有机碳AMS 14C测年结果更可信。     

西伯利亚极地海域表层沉积硅藻分布特征及其与海洋环境变量的相关性研究

北冰洋西伯利亚陆架海是北极气候快速变化最为显著的海域之一,而沉积硅藻作为极地海洋生态系统的重要组成部分,对环境变化具有敏感的响应。对楚科奇海、东西伯利亚海和拉普捷夫海表层沉积物开展了硅藻组成鉴定,利用典型对应分析方法分析了硅藻属种与1986～2015年环境变量之间的关系。结果表明,夏季和秋季海冰密集度、表层海水盐度是影响研究区表层硅藻分布特征最主要的因素。此外,根据表层站位与环境变量的典型对应分析,可将西伯利亚极地海域划分为4个区域,分别为海冰硅藻组合带、暖水硅藻组合带、沿岸硅藻组合带和混合硅藻组合带。这些表层站位的分区与相应区域的海流模式有明显的相关性,海冰硅藻组合带仅分布于研究区北部的高纬度地区;暖水硅藻组合带位于受白令水和太平洋海水的分支——阿拉斯加沿岸水影响为主的区域;拉普捷夫海南部的沿岸硅藻组合带则受到河流径流和西伯利亚沿岸流的强烈影响;混合硅藻组合带受极地冷水、海冰覆盖、太平洋暖水和陆地径流的共同影响。     

普里兹湾及邻近海区表层沉积硅藻分布与环境分析

表层沉积物中硅藻的分布及组合特征对于研究相应的海洋环境有着重要的意义。东南极普里兹湾及其附近海域的22站表层沉积物中鉴定出硅藻36种,分属13属,其中Fragilariopsis curta在普里兹湾内占36.76%~66.36%,Fragilariopsis kerguelensis在湾外开阔水域占54.33%~70.95%。除趋势对应分析(DCA)显示研究区主要的10种硅藻分为开放水域种组合、近海冰种组合和海冰种组合,其表层沉积硅藻组合分布也分成3个区。作为硅藻极地开放海洋指示种的Fragilariopsis kerguelensis分布在普里兹湾外的深海平原,受湾内冰架水的限制,不能向湾内扩散;作为硅藻海冰指示种的Fragilariopsis curta主要分布在普里兹湾内的陆架上,受南极表层水和海冰的影响较重,在湾外受深水溶解作用而急剧减少;作为硅藻近海冰指示种的Thalassiosira antarctica的出现是受普里兹环流、冰架水和海冰的控制。研究区硅藻的组成和分布反映和验证了区域内环流的分布和扩散极限。     

白令海北部悬浮体含量分布及其颗粒组分特征

对中国第四次北极科学考察期间在白令海北部获取的海水样品进行悬浮体含量及其颗粒组分特征的分析。结果表明,白令海陆架海区悬浮体含量大体呈现出表层浓度低而底层浓度高的特点。表层海水悬浮体含量在白令海峡西侧和陆架东侧靠近阿拉斯加沿岸含量较高,而底层海水中悬浮体含量则在白令海峡西侧,以及白令海陆架西南部的圣马修岛西北侧较高。陆架流系对底床物质的再悬浮作用致使白令海悬浮颗粒物浓度的高值区多位于近底层海水中。受白令陆坡流沿陆架坡折带输运作用,研究区西南部悬浮体浓度较高。白令海陆架水以及阿纳德尔流携带悬浮颗粒向北输运,使得底层悬浮体浓度呈现出自南向北逐渐减弱的模式。圣劳仑斯岛以北靠近楚科奇半岛一侧海域,受高营养盐的阿纳德尔流的影响,悬浮颗粒物以藻类为主;东侧阿拉斯加沿岸流区悬浮颗粒则以陆源的碎屑矿物为主。     

白令海与西北冰洋表层沉积物粒度分布特征及其环境意义

基于中国第2次至第5次北极科学考察以及俄罗斯科学院远东分院太平洋海洋研究所提供的表层沉积物样品,开展粒度分析,研究表层沉积物粒度特征及其变化规律对沉积环境的指示意义。白令海与北冰洋表层沉积物类型比较丰富,沉积物主要来源于陆源碎屑,搬运方式以河流、海岸侵蚀、冰筏为主,辅以洋流。沉积物类型主要因为沉积物搬运方式及距离的远近产生差异,白令海北部及楚科奇海南部表层沉积物粒度随着离陆地距离的增大而逐渐减小,高纬地区的沉积物因冰筏沉积作用而分选较差。     

白令海表层营养盐水平输送的镭-228示踪

对白令海表层海水228Ra的分析表明,白令海表层海水228Ra比活度从低于检测限变化至0.81 Bq/m3,低于西北冰洋陆架区的报道值。表层水228Ra比活度和228Ra/226Ra)_A.R.的空间分布均呈现由西南部中心海盆向东北部陆架区增加的趋势。由228Ra/226Ra)_A.R.和盐度的关系揭示出白令海环流、白令海陆坡流和阿拉斯加沿岸流对228Ra和228Ra/226Ra)_A.R.分布有明显影响。运用一维稳态扩散模型计算出白令海由中心海盆向东北部陆架方向上水体混合的水平涡动扩散系数为1.9×108 m2/d。结合海盆-陆架界面营养盐的水平浓度梯度,估算得硝酸盐、活性磷酸盐和活性硅酸盐由白令海中心海盆向东北部陆架区的水平输送通量,该通量对白令海东北部陆架区新生产力的贡献很小,其他途径输送的营养盐更为重要。     

白令海及西北冰洋有机质来源与新鲜程度的脂肪酸指示

白令海、西北冰洋等高生产力海域在北冰洋“生物泵”中起到重要作用；海水升温、海冰消退等北极快速变化，将强烈影响该海域“生物泵”的结构与规模，并在沉积物中有机质的来源与新鲜程度上有所体现，可用脂肪酸加以指征。对第五次、第六次中国北极科学考察在以上海域采集的表层沉积物进行脂肪酸含量（以沉积物干重计）及组成分析，结果显示楚科奇海陆架总脂肪酸含量非常高((97.15± 55.31) μg/g)，白令海盆最低((15.00±1.30) μg/g)，加拿大海盆、楚科奇海陆坡、白令海陆架居中(分别为(88.65 ± 3.52) μg/g，(70.35±11.32) μg/g与(38.28±14.89) μg/g)。海源脂肪酸占总脂肪酸比例最高(86.82%±7.08%)，陆源次之(8.45%±6.62%)，细菌最低(4.63%±2.24%)；硅藻指数(16:1ω9/16:0)在楚科奇海陆架(> 0.82)、白令海陆架边缘(> 0.65)较高，其他区域均较低。脂肪酸结果表明:(1) 该海域沉积有机质主要来自海源，陆源贡献小；在北部、南部楚科奇海陆架、白令海陆架边缘，硅藻生物量占主要优势；细菌脂肪酸比例显著低于温暖海域，指示低温抑制细菌活动。(2) 楚科奇海陆架区硅藻生产力高、细菌活动弱，新鲜有机质沉降效率高，但对未来海水升温、浮游植物群落变化也较为敏感。(3) 加拿大海盆、楚科奇海陆坡的浮游植物群落由绿藻与金藻主导。以上结论说明脂肪酸可指示表层沉积物中有机质的来源与新鲜程度；未来，脂肪酸有望进一步揭示北冰洋“生物泵”对北极快速变化的响应。     

白令海北部表层沉积物中的生源组分分布特征及其古海洋学意义

对中国首次和第3次北极科学考察在白令海北部所采取的29个表层沉积物中的TOC、生源Opal和CaCO3含量等进行了研究,结果发现,TOC的高值出现在外陆架至中陆架区,其次为海盆区,白令海峡至内陆架最低;Opal的高值出现在海盆至陆坡边缘区,其次为外陆架至中陆架,白令海峡至内陆架最低;CaCO3的高值出现在内陆架至中陆架...     

2008年夏季白令海营养盐的分布及其结构状况

中国第3次北极考察对白令海营养盐的分布及结构状况进行了观测分析,结果表明,白令海营养盐分布和结构状况区域性特征明显。海盆区表层DIN、磷酸盐和硅酸盐平均浓度分别为9.73,0.94,11.06 μmol/dm3;陆架区表层DIN,磷酸盐和硅酸盐平均浓度分别为0.60, 0.43, 3.74 μmol/dm3。营养盐高值主要出现在白令海西南部的海盆区和海峡口西南侧水域,低值出现于陆架边缘的陆坡区和陆架东部水域。白令海盆区真光层DIN,磷酸盐、硅酸盐浓度普遍较高,叶绿素浓度则较低,具有典型的高营养盐、低叶绿素(HNLC)特征。海盆区生物作用不是营养盐空间分布的主要调控因子,而陆架区营养盐的分布变化不仅受控于物理海洋输运过程的变化,同时也受夏季浮游生物生长、营养盐吸收消耗所影响。陆架和陆坡区表层海水N/P,Si/P比值平均分别为1.8, 9.9和3.2, 2.2,呈明显的低N/P,Si/P比值结构特征,陆坡区缺硅明显,陆架区缺氮显著。在白令海水域磷酸盐浓度普遍较高,它不可能成为浮游植物光合作用限制因子。受硅限制水域主要限于陆坡区硅藻大量繁殖时期,属偶然性限制,在白令海陆架区绝大部分水域主要表现为氮限制。     

白令海北部陆坡23 ka以来古生产力变化及其对海冰扩张的响应

本文基于白令海北部陆坡ARC6-B11岩心的沉积物粒度、颜色反射率、有机碳/氮含量和高分辨率化学元素XRF扫描数据，结合底栖和浮游有孔虫AMS14C测年资料，重建了研究区23 ka以来至中全新世的沉积记录，重点研究了海冰的扩张变化对生产力和沉积物输入的影响。研究结果显示，末次盛冰期白令海北部陆坡受到海冰南向扩张的影响而生产力较低，沉积物中砂粒级和冰筏碎屑（IRD）含量较高。HS 1时期由于受到常年冰的覆盖，沉积物中砂粒级和IRD含量存在低值，沉积物中较高的总有机碳（TOC）含量受陆源有机质的影响较大，异常的TOC含量峰值主要受到低海平面和海冰形成过程产生的富氧水团控制下的高浓度细粒物质携带的陆源有机质的快速沉积作用的影响，难以作为反映白令海古生产力的替代指标。B/A暖期和全新世生产力较高，在B/A暖期存在Ca/Ti峰值现象，Ca/Ti峰值现象的产生与碳酸盐补偿深度增加有关，水体通风条件的改变可能起到一定的作用，也不能忽视颗石藻对其产生的潜在影响。     

白令海夏季浮游植物的群落结构与时空变化

通过1999年和2010年夏季同期7月在白令海(169°E~166°W,50°N~67°N)获取的94份浮游植物样品分析,获得了近十年的始末两个时间节点的浮游植物群落结构与时空变化,探讨了浮游植物群落动态及其与环境因素的关联。研究结果显示,共鉴定浮游植物(>10μm)5门58属153种,分为3个生态类群。硅藻是浮游植物的主体,种类多丰度高,占总种类数目的66.7%,占总丰度的95.2%。鉴于样品属性和空间范围的不同,物种组成有细微差别,丰度有较大差异且空间分布明显不同,高丰度区受控于上层营养盐供给和表层环流系统。优势种从北方温带大洋性硅藻演变为广温广盐性与冷水性硅藻,1999年以西氏新细齿状藻为第一优势种,柔弱伪菱形藻次之;2010年以丹麦细柱藻为第一优势种,冷水性的诺登海链藻次之并在陆架和陆坡占优。浮游植物群落结构较为稳定,由深水群落和浅水群落组成。深水群落分布于太平洋西北部和白令海盆,种类组成以温带大洋性的西氏新细齿状藻、长海毛藻、大西洋角毛藻和广布性的菱形海线藻、扁面角毛藻、笔尖根管藻为主,丰度低,种间丰度分配均匀,优势种多元化,物种多样性高;浅水群落分布于白令海陆坡和陆架,主要由冷水性的诺登海链藻、叉尖角毛藻、聚生角毛藻和广布性的丹麦细柱藻、旋链角毛藻组成,丰度高,种间丰度分配不均匀,优势种突出,物种多样性低。白令海夏季浮游植物种类组成及丰度变化直接受控于表层环流、营养盐、春季冰缘线等环境因素。     

白令海大型底栖动物群落结构及其空间分布格局

Due to its unique geological location, the Bering Sea is an ideal place to investigate the water exchange and ecosystem connectivity of the Pacific Ocean–Arctic Ocean and subarctic–Arctic region. Based on a number of summer surveys(July to September, 2010, 2012 and 2014), macrobenthic communities and their spatial-temporal patterns are exhibited for the majority of the Bering Sea(53°59′–64°36′N). The results show that the macrobenthic communities were dominated by northern cold-water species and immigrant eurythermic species, and the communities assumed a dispersed and patchy distribution pattern. Polychaetes(Scoloplos armiger), crustaceans(Ceradocus capensis) and sea urchins(Echinarachnius parma) were the main dominant groups in the shallow shelves; the sea star(Ctenodiscus crispatus) and the brittle star(Ophiura sarsii) were the main dominant groups in the continental slope; whereas small polychaetes(Prionospio malmgreni) dominated the basin area. Sediment type, water depth, and currents were the major factors affecting the structure and spatial distribution of the macrobenthic communities. Compared with other seas, the shallow areas of the Bering Sea showed an extremely high-standing biomass. In particular, the northern shelf area(north of St. Lawrence Islands and west of 170°W),which is primarily controlled by Anadyr Water, is an undersea oasis. In contrast, a deficiency in the downward transport of particulate organic carbon has resulted in a desert-like seabed in the basin area. By comparing our results to previous studies, we found that macrobenthic communities of the Bering Sea have undergone significant structural changes in recent decades, resulting in a decrease in abundance and an increase in biomass.In addition, populations of amphipods and bivalves in the northern shelves have decreased significantly and have been gradually replaced by other species. These changes might be associated with advanced seasonal ice melting,changes in organic carbon input, and global warming, indicating that large-scale ecosystem changes have been occurring in the Bering Sea.     

Phytoplankton composition and its ecological effect in subsurface cold pool of the northern Bering Sea in summer as revealed by HPLC derived pigment signatures

CHEMTAX analysis of high-performance liquid chromatography(HPLC) pigment was conducted to study phytoplankton community structure in the northern Bering Sea shelf, where a seasonal subsurface cold pool emerges. The results showed that fucoxanthin(Fuco) and chlorophyll a(Chl a) were the most abundant diagnostic pigments, with the integrated water column values ranging from 141 to 2 160 μg/m2 and 477 to 5 535 μg/m2, respectively. Moreover, a diatom bloom was identified at Sta. BB06 with the standing stock of Fuco up to 9 214 μg/m3. The results of CHEMTAX suggested that the phytoplankton community in the northern Bering Sea shelf was dominated by diatoms and chrysophytes with an average relative contribution to Chl a of 80% and 12%, respectively, followed by chlorophytes, dinoflagellates, and cryptophytes. Diatoms were the absolutely dominant algae in the subsurface cold pool with a relative contribution exceeding 90%, while the contribution of chrysophytes was generally higher in oligotrophic upper water. Additionally, the presence of a cold pool would tend to favor accumulation of diatom biomass and a bloom that occurred beneath the halocline would be beneficial to organic matter sinks, which suggests that a large part of the phytoplankton biomass would settle to the seabed and support a rich benthic biomass.     

Foraminifera in surface sediments of the Bering and Chukchi Seas and their sedimentary environment

Based on a quantitative analysis of foraminifera in 39 surface samples of the Bering andChukchi Seas, the nearly absence of planktonic foraminifera in the surface sediments can be related to the low surface primary productivity and strong carbonate dissolution in the study area. It has been revealed that the surface primary productivity, and carbonate dissolution and properties of water masses related to the water depth mainly control the distribution of benthic foraminifera. The shelf of the Chukchi Sea is dominated by the Elphidium spp. assemblage and Nonionella robusta assemblage with low foraminiferal abundance and diversity, which is controlled by the coastal water mass of the Arctic Ocean. The slope of the Bering Sea is dominated by the Uvigerina peregrina - Globobulimina affinis assemblage with abundant N. robusta, and relatively high foraminiferal abundance and diversity, which is controlled by the intermediate and deep water masses of the Pacific Ocean. However, the Bering Sea has relatively sha     

Combining field observations and modeling approaches to examine Greenland halibut (Reinhardtius hippoglossoides) early life ecology in the southeastern Bering Sea

Spawning in Greenland halibut (Reinhardtius hippoglossoides) occurs along the continental slope and in submarine canyons in the eastern Bering Sea. It is assumed that these bathymetric features and their associated circulation patterns deliver eggs and larvae to suitable nursery habitats over the continental shelf. However, there have been no directed field studies examining spawning areas or transport of Greenland halibut early life stages in the Bering Sea, nor is it known how large-scale oceanographic forcing modulates specific physical mechanisms of delivery. The present study was undertaken to: better define spawning areas of Greenland halibut, examine development and distribution of larvae, and understand the influence of climate variations on interannual patterns of transport, distribution and abundance. Eggs were found in Bering and Pribilof Canyons and over the adjacent slope in February and early March, confirming that spawning occurs in these regions. Larvae were present over the slope, outer shelf and middle shelf in winter and spring, and settled juveniles were collected over the shelf in September. Oceanographic modeling approaches that simulate larval advection from spawning to nursery habitats indicate that depth-discrete variations in transport pathways from submarine canyons to the adjacent shelf contribute to interannual variability in transport trajectories. Overall, our results highlight specific physical mechanisms of delivery that are modulated by large-scale atmospheric and oceanographic forcing, potentially varying the degree of slope–shelf connectivity for Greenland halibut and other slope-spawning species.     

白令海和楚科奇海表层沉积中的有孔虫及其沉积环境

通过对白令海和北冰洋楚科奇海39个表层沉积样品中有孔虫的定量分析,发现表层沉积中浮游有孔虫稀少可能与该区表层生产力低、碳酸盐溶解作用较强有关,而底栖有孔虫的分布则主要受表层初级生产力以及与水深相关的碳酸盐溶解作用和水团性质所控制,其中北冰洋楚科奇海陆架区有孔虫以Elphidium spp.组合和Nonionella robusta组合为主,丰度和分异度低,受北冰洋沿岸水团控制;白令海陆坡区有孔虫以Uvigerina peregrina-Globobulimina affinis组合为主,含N.robusta较多,丰度和分异度相对高,受太平洋中层和深层水团控制,但该区碳酸盐溶跃层和补偿深度(CCD)相对浅,约分别位于2000和3800m处.此外,白令海陆坡上部表层沉积中含有北冰洋陆坡区典型深水底栖有孔虫种Stetsonia arctica,说明白令海峡两侧的海区曾有深部水交流.     

Phytoplankton of the western Arctic in the spring and summer of 2002: Structure and seasonal changes

We analyzed the taxonomic structure and spatial variability of phytoplankton abundance and biomass in the Chukchi and Beaufort Seas during spring and summer seasons of the SBI program. Phytoplankton samples were collected during two surveys from May 10 to June 13 and from July 19 to August 21 of 2002. In May and June, ice cover exceeded 80% over most of the study area and there was no vertical stratification, indicating that the successional state of the phytoplankton corresponded to the end of the winter biological season. The phytoplankton abundance ranged from a few tens to a few thousands of cells per liter, while biomass varied from 0.1 to 3.0 mg C m⁻³. Small areas of high phytoplankton abundance (0.13–1.3×10⁶ cells L⁻¹) and biomass (22–536 mg C m⁻³), dominated by early spring diatoms Pauliella taeniata and Fragilariopsis oceanica in the surface waters, which indicated the beginning of the spring bloom, were observed only in the southeastern part of the Chukchi shelf and off Point Barrow. In July and August summer period, more than a half of the study area had <50% ice cover and the water column was stratified by temperature and salinity. Over the Chukchi shelf and continental slope of the Beaufort Sea, the phytoplankton abundance and biomass were an order of magnitude higher in July–August than in May–June. The taxonomic diversity of algae also increased due to the appearance of late-spring and summer diatoms, dinoflagellates, and coccolithophorids (Emiliania huxleyi). Interestingly, the seasonal differences between phytoplankton abundance and taxonomic composition in the spring and summer periods varied the least over the Chukchi Sea slope and in the deep-water area of the Arctic Ocean. High algae concentrations in summer were located in the lower layers of the euphotic zone, suggesting that the spring bloom on both the Chukchi shelf and in the western part of the Beaufort Sea occurred in late June/early July. In the spring and summer, the microalgal community was characterized by a high abundance of 4–10 μm flagellates, which exceeded the abundance of all other taxonomic groups. In both seasons studied, phytoplankton reached its maximum abundance within restricted areas in the southern part of the Chukchi Sea southwest of Point Hope, in the northern part of the Chukchi shelf between the 50- and 100-m isobaths, on the shelf northwest of Point Barrow, and over the continental slope in the Beaufort Sea. The pronounced spatial difference in the seasonal state was a characteristic feature of the phytoplankton community in the western Arctic.