西格陵兰附近海域表层沉积硅藻组合

通过对西格陵兰附近海域表层沉积硅藻进行研究,并运用对应分析方法对硅藻种属及站点进行分析处理,研究结果表明,海冰种和极地种为该海域的优势种,而暖水种主要分布在拉布拉多海.根据对应分析站点的得分情况,将35个站点划分为5个硅藻组合,并对每个组合分布区域的环境影响因子,如:洋流、极地水团、陆地冰川融水等进行了分析,结果证明西...     

中国南海表层沉积硅藻的分布及其与环境关系探讨

通过对中国南海62个站位表层沉积硅藻的分析,查明研究海区硅藻的种类组成及分布特点。共鉴定到硅藻56属的235个种(包括变种和变型),以热性外洋种为优势,伴有一定量的近岸广布种。总体上,南海硅藻丰度变化呈现从陆架向陆坡至海盆递增的趋势。根据表层沉积硅藻中具有指示意义的硅藻种的分布和生态变化,划分6个硅藻组合带,各组合分别反映不同的海洋环境,其分布主要受到海洋环流的影响,表现为黑潮暖流、印度洋暖水的入侵以及沿岸流对南海表层沉积硅藻分布的影响。与南海相邻海区硅藻种类比较结果表明,研究海区表层沉积硅藻种类组成与临近的菲律宾海域相似程度最大,其次是中国东海海域、太平洋东北部海域。     

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。     

冰岛北部陆架末次冰消期以来基于硅藻的古环境记录

冰岛北部陆架MD99-2271孔沉积硅藻组合呈现暖水硅藻数量增加、冷水硅藻数量减少和这两类硅藻数量周期性此消彼长的特点,反映了气候在趋暖的背景下,冷暖交替的过程。通过该区温度指数Rw/wc值(暖水硅藻种含量与海冰种及暖水种含量总和的比值)的变化,重建了冰岛北部陆架古海洋环境:Blling-Allerd暖期时,暖水硅藻T.nitzschioides含量较高,表明印明格暖流对研究区的影响较强;随着暖水硅藻含量减少,海冰硅藻F.cylindrus和T.bulbosa的显著增加,此时暖流强度减弱,东格陵兰寒流明显增强,冰岛北部海域进入末次冰消期以来最冷的时期——Younger Dryas冷期。11cal.kaBP左右暖水硅藻T.nitzschioides和T.oestrupii数量急剧升高,表明该海域海洋环境发生了明显变化,并逐步向全新世大暖期过渡,此时冰岛北部陆架海域现代海洋格局基本形成。全新世大暖期时,硅藻群落表现为暖水种的显著增多,海冰、极地及冷水硅藻较之前明显减少,说明冰岛北部海域主要受北大西洋暖流的分支——印明格暖流的影响,海洋环境较温暖;6cal.kaBP之后东格陵兰寒流逐渐增强,冰岛北部海洋环境转冷,全新世大暖期结束。     

西北冰洋表层沉积物黏土矿物分布特征及物质来源

西北冰洋表层沉积物黏土矿物分析结果显示其黏土矿物组成的区域分布和变化具有明显的规律性:从楚科奇海到北冰洋深水区,随着水深的增加,蒙皂石和高岭石含量增高,绿泥石和伊利石含量降低。自西往东,伊利石结晶度值降低,化学指数升高。根据Q型聚类分析获得的黏土矿物组合特征,结合周缘陆地的地质背景、河流及洋流情况,对研究区进行了黏土矿物组合分区,讨论了其黏土矿物来源。楚科奇海表层沉积物黏土矿物组合在靠近阿拉斯加一侧海域以Ⅰ类为主,靠东西伯利亚海一侧主要有Ⅱ类、Ⅲ类和Ⅳ类,中部主要为Ⅵ类,主要是西伯利亚和阿拉斯加的火山岩、变质岩以及一些含高岭石的沉积物以及古土壤等,经风化、河流搬运入海,在北太平洋的3股洋流及西伯利亚沿岸流的作用下沉积形成的。西北冰洋深水区表层沉积物的黏土矿物组合以Ⅰ类和Ⅴ类为主,表明其沉积物来源为欧亚陆架和加拿大北极群岛周缘海域的海冰沉积和大西洋水体的搬运以及加拿大马更些河的河流物质输入。     

东北季风初期台湾北部沿岸海域浮游动物的特点

本文报道台湾北部沿岸海域东北季风初期浮游动物的特点。台湾西北沿岸海的浮游动物生物量和密度高于台湾岸海域,但是浮游动物种类在东北沿岸海域却较丰富。台湾西北沿岸海域浮游动物属于暖水近岸种类,来自在台湾海峡从南到北暖流。台湾东北沿岸海域浮游动物群落包含来自东海陆架水的种类例如中华哲水蚤、太平洋磷虾, 含有黑潮水的热带暖水近岸种。     

我国东南近岸海域表层沉积硅藻组合

对采自我国东南近岸海域18个站位78个表层沉积样品进行了硅藻鉴定分析,根据硅藻优势种和次优势种的分布特征,划分出3个组合和两个亚组合,其较好地对应分布于南海、台湾海峡和东海等3个近岸海域。统计数据表明,近岸海域表层沉积硅藻的分布受大陆入海径流的影响微乎其微,随着水深的增加,我国东南近岸海域海洋初级生产力减小,底栖种、潮间带种减少而浮游种增加;组合Ⅰ的分布表明南海东北部海域明显受黑潮流等外洋水团的影响,可应用组合Ⅱ1和组合Ⅱ2中优势种和特征种硅藻来指示水深,两亚组合面貌的差异是对冬夏两季海峡两侧受不同性质海流控制的响应;组合Ⅲ受沿岸流控制比较明显,而遭受黑潮等外洋水团的影响很弱。     

北冰洋西部表层沉积物中生源组分及其古海洋学意义

通过对中国首次和第二次北极科学考察在北冰洋西部所采取的66个表层沉积物中生源组分的分析,探讨了该海区表层生产力变化与水团的相互关系。楚科奇海西南部呈现出高的有机碳和生源蛋白石含量,而中部和东部哈罗德浅滩至阿拉斯加沿岸,以及楚科奇海台、北风脊和加拿大海盆表现出低的有机碳和生源蛋白石含量。楚科奇海陆架区表层沉积物以底栖有孔虫为主,丰度低;而楚科奇海台、北风脊和加拿大海盆则以浮游有孔虫占绝对优势,丰度较高。生源组分的分布特征显然与通过白令海峡进入楚科奇海的三股太平洋水和大西洋次表层水相关。楚科奇海西侧沿富营养的阿纳德尔流方向的区域呈现出高的表层生产力。而东侧受寡营养的阿拉斯加沿岸流及阿拉斯加西北沿岸陆源物质输入的影响,呈现出低的表层生产力。北纬75°以北及加拿大海盆受海冰覆盖影响,也表现出最低的表层生产力。而受北大西洋次表层水的影响,楚科奇海陆架外侧高纬海域表现出较高的钙质生物生产力。表层沉积物中Corg/N比值及其分布反映楚科奇海表层沉积物中的有机碳以海洋自身来源为主,且主要受生物泵过程控制。有机碳和生源蛋白石含量呈现高的正相关关系,说明硅藻等浮游植物的初级生产力可能控制着生物泵对碳的吸收和释放。     

基于卫星数据的北极海冰变化分析

海冰是极地气候系统重要组成部分。基于1982—2004年的卫星反照率、海冰密集度数据,选取了7个北极海域(分别位于格陵兰海、巴伦支海、喀拉海、拉普捷夫海、东西伯利亚海及以北海域、楚科奇海及以北海域和波弗特海及以北海域)进行了研究。对比分析发现,两数据区域平均序列相关性比较高,最低相关系数为0.51,最高相关系数为0.94。格陵兰海海域和巴伦支海海域夏季海表反照率、海冰密集度较低,多为无冰海面;喀拉海域、拉普捷夫海域、东西伯利亚海及以北海域6月份海表反照率、海冰密集度较高,7、8月份海冰加速融化,海冰密集度下降明显;楚科奇海及以北海域、波弗特海及以北海域夏季海表反照率、海冰密集度较高。7个海域海表反照率、海冰密集度均呈现下降趋势,西部的楚科奇海及以北海域、波弗特海及以北海域下降速度最快,巴伦支海海域下降速度最慢。海表反照率和海冰总量的减少,对气候演变有着重要影响。     

2008年夏季西北冰洋表层水浮游植物群落结构的色素表征及其对不同水团的响应

本文依托2008年夏季中国第三次北极科学考察航次,对西北冰洋海盆区和楚科奇海陆架营养盐及光合色素进行了测定和分析。根据海水理化性质将研究海区分为5个区,并使用CHEMTAX软件（Mackery et al.,1996）讨论了西北冰洋不同海区浮游植物群落组成结构及其与环境因子之间的关系。结果显示在楚科奇海陆架区,太平洋入流显著影响浮游植物生物量和群落结构。高营养盐Anadyr水团以及白令陆架水控制海域,表现出高Chl a且浮游植物以硅藻为主,相反,低营养盐如阿拉斯加沿岸流控制海域,Chl a生物量低且以微型,微微型浮游植物为主。在外陆架海区,海冰覆盖情况影响着水团的物理特征及营养盐浓度水平,相应地显著影响浮游植物群落结构。在海冰覆盖区域,硅藻生物量站到总Chl a生物量的75%以上;在靠近门捷列夫深海平原海区,受相对高盐的冰融水影响（MW-HS）,营养盐浓度和Chl a浓度相对海冰覆盖区略高,浮游植物结构中微型、微微型藻类比重增加,硅藻比例则降至33%;南加拿大海盆无冰海区（IfB）,表层水盐度最淡,营养盐浓度最低,相应地显示出低Chl a生物量,表明海冰消退,开阔大洋持续时间延长,将导致低生物量及激发更小型浮游植物的生长,并不有利于有机碳向深海的有效输出。     

2013年北极最小海冰范围比2012年增加的原因分析

北极海冰范围从1979年有卫星观测资料以来呈现明显下降趋势,尤其是9月份。2012年9月北极海冰范围达到有观测记录以来的最小值,而2013年9月比2012年同期增加了60%。增加的区域主要在东西伯利亚海区、楚科奇海和波弗特海区。本文应用距平和经验模态分解方法,分析了美国国家冰雪数据中心的北极海冰卫星数据、欧洲预报中心的夏季底层大气环流数据和上层海洋的温度,指出2013年北极最小海冰范围比2012年在北冰洋太平洋扇区增加的原因,是由于表面气温(SAT)降低、海平面气压(SLP)升高、气旋式风场异常、表面空气中水汽含量(SH)降低以及海表面温度(SST)降低5个条件形成的冰-SAT、冰-SST和冰-汽(SH)3个正反馈机制共同作用造成的。     

巴芬湾西部和格陵兰岛东部大气经向热量输送协同变化对夏季北极海冰的影响

利用欧洲中心气候再分析资料和美国国家冰雪数据中心北极海冰面积资料，分析了夏季北极海冰面积与前期大气经向热量输送年际变化的联系。结果表明：6月北半球中高纬大气的经向热量输送以瞬变热量形式为主，其中巴芬湾西部（B区）和格陵兰岛东部（G区）是瞬变热量向极区传输的两个通道，二者之间存在反位相的协同变化，且这种协同变化与夏季北极海冰面积变化密切相关。可能的机制为：6月，AD、AO和NAO三种北极大气环流型能够引起巴芬湾西部和格陵兰岛东部瞬变热量输送的协同变化，这种协同变化通过涡旋动力作用激发夏季极区大气表现为AD异常，同时影响途经区域的气温，从而通过热动力作用影响夏季北极海冰。将向极区输送的热量称为暖输送，从极区输出的热量为冷输送，则上述两个区域的瞬变热量协同输送可分为三种情况：B暖G冷、B冷G暖、B和G均冷，而B和G均暖的情况十分罕见。当B区向极区输入、G区输出热量时，有利于太平洋扇区和喀拉海的海冰偏少；当G区输入、B区输出热量时，利于喀拉海和拉普捷夫海海冰偏少；当B区和G区均输出热量时，利于波佛特海南部、喀拉海和拉普捷夫海海冰偏多，反之则相反。     

2003-2012年间白令海峡断面淡水构成的时空变化

通过对2003-2012年间白令海峡64.3°N断面海水氧同位素组成的分析,应用海水δ18 O值和盐度的质量平衡关系区分出淡水中河水和海冰融化水组分的贡献,探讨白令海峡淡水组成的分布特征及其年际变化。研究表明,断面东侧阿拉斯加沿岸水影响区呈现低δ18 O值、低盐、高温、高河水组分的特征,西侧阿拉德尔水具有高δ18 O值、高盐、低海冰融化水的特征,中部白令陆架水的δ18 O值、盐度和淡水组成则居于上述二者之间。阿拉斯加沿岸水影响区河水组分的份额约为阿拉德尔水和白令陆架水的2倍,并呈现出2010年2012年2003年2008年的时间变化规律,受控于育空河入海径流量的时间变化。白令陆架水和阿拉斯加沿岸水影响区的海冰融化水份额较为接近,均比阿拉德尔水影响区的海冰融化水份额高约45%。海冰融化水的年际变化表现出2003年2008年≈2012年2010年的规律,受控于白令海海冰的年际变动。从断面淡水构成看,通过白令海峡的淡水平均由46%的河水和54%的海冰融化水构成,且阿拉德尔水、白令陆架水和阿拉斯加沿岸水影响区河水组分与海冰融化水组分的比值自2003年至2012年间呈增加趋势,证明太平洋入流中淡水构成的变化对北冰洋海冰的融化也起着一定的作用。     

Severe winter weather as a response to the lowest Arctic sea-ice anomalies

Possible impact of reduced Arctic sea-ice on winter severe weather in China is investigated regarding the snowstorm over southern China in January 2008. The sea-ice conditions in the summer （July-September） and fall （September-November） of 2007 show that the sea-ice is the lowest that year. During the summer and fall of 2007, sea ice displayed a significant decrease in the East Siberian, the northern Chukchi Sea, the western Beaufort Sea, the Barents Sea, and the Kara Sea. A ECHAM5.4 atmospheric general circula- tion model is forced with realistic sea-ice conditions and strong thermal responses with warmer surface air temperature and higher-than-normal heat flux associated with the sea-ice anomalies are found. The model shows remote atmospheric responses over East Asia in January 2008, which result in severe snowstorm over southern China. Strong water-vapor transported from the Bay of Bengal and from the Pacific Ocean related to Arctic sea-ice anomalies in the fall （instead of summer） of 2007 is considered as one of the main causes of the snowstorm formation.     

北极和南极表面温度对中低纬度海洋热强迫的响应

利用耦合了平板海洋模型的全球气候模式进行了大量的格林函数实验,以探究两极地区对于施加在中低纬度海域的热强迫的气候响应。结果表明,北极地区的气候不仅受到距离较近的北太平洋与北大西洋的影响,远离北极的热带太平洋以及南太平洋也对其气候有显著的影响,南极地区的气候则主要是受到邻近的南大洋的影响。通过经验正交函数法的进一步分析发现,北极响应最显著的区域包括波弗特海(Beaufort Sea)、拉普捷夫海(Laptev Sea)以及北极中心区附近;南极地区的响应主要集中在别林斯高晋海(Bellinsgauzen Sea)区域。另外,利用温度归因法对辐射反馈过程和大气能量输运分解发现,北极地区表面温度的响应主要是受到了反照率反馈以及垂直递减率反馈的影响,而南极地区的响应则主要是反照率反馈发挥了作用。     

2008年夏季加拿大海盆永久冰区的淡水累积现象

A combination of δ~(18)O and salinity data was employed to explore the freshwater balance in the Canada Basin in summer 2008.The Arctic river water and Pacific river water were quantitatively distinguished by using different saline end-members.The fractions of total river water,including the Arctic and Pacific river water,were high in the upper 50 m and decreased with depth as well as increasing latitude.In contrast,the fraction of Pacific river water increased gradually with depth but decreased toward north.The inventory of total river water in the Canada Basin was higher than other arctic seas,indicating that Canada Basin was a main storage region for river water in the Arctic Ocean.The fraction of Arctic river water was higher than Pacific river water in the upper 50 m while the opposite was true below 50 m.As a result,the inventories of Pacific river water were higher than those of Arctic river water,demonstrating that the Pacific inflow through the Bering Strait is the main source of freshwater in the Canada Basin.Both the river water and sea-ice melted water in the permanent ice zone were more abundant than those in the region with sea-ice just melted.The fractions of total river water,Arctic river water,Pacific river water increased northward to the north of 82°N,indicating an additional source of river water in the permanent ice zone of the northern Canada Basin.A possible reason for the extra river water in the permanent ice zone is the lateral advection of shelf waters by the Trans-Polar Drift.The penetration depth of sea-ice melted waters was less than 30 m in the southern Canada Basin,while it extended to 125 m in the northern Canada Basin.The inventory of seaice melted water suggested that sea-ice melted waters were also accumulated in the permanent ice zone,attributing to the trap of earlier melted waters in the permanent ice zone via the Beaufort Gyre.     

Probable limits of sea ice extent in the northwestern Subarctic Pacific during the last glacial maximum

The article summarizes and analyzes published data on the distribution of sea-ice and open-ocean diatoms in 42 cores of bottom sediments from the northwestern part of the Subarctic Pacific that accumulated during the last glacial maximum (LGM). Based on micropaleontological records, the extent of winter sea ice during the LGM could be limited to the Okhotsk and Bering seas. During the warm season, the surface water masses from the open Subarctic Pacific spread widely in the marginal seas.     

北极各海域海冰覆盖范围的变化特征

Sea ice in the Arctic has been reducing rapidly in the past half century due to global warming.This study analyzes the variations of sea ice extent in the entire Arctic Ocean and its sub regions.The results indicate that sea ice extent reduction during 1979–2013 is most significant in summer,following by that in autumn,winter and spring.In years with rich sea ice,sea ice extent anomaly with seasonal cycle removed changes with a period of 4–6 years.The year of 2003–2006 is the ice-rich period with diverse regional difference in this century.In years with poor sea ice,sea ice margin retreats further north in the Arctic.Sea ice in the Fram Strait changes in an opposite way to that in the entire Arctic.Sea ice coverage index in melting-freezing period is an critical indicator for sea ice changes,which shows an coincident change in the Arctic and sub regions.Since 2002,Region C2 in north of the Pacific sector contributes most to sea ice changes in the central Aarctic,followed by C1 and C3.Sea ice changes in different regions show three relationships.The correlation coefficient between sea ice coverage index of the Chukchi Sea and that of the East Siberian Sea is high,suggesting good consistency of ice variation.In the Atlantic sector,sea ice changes are coincided with each other between the Kara Sea and the Barents Sea as a result of warm inflow into the Kara Sea from the Barents Sea.Sea ice changes in the central Arctic are affected by surrounding seas.     

Dense water formation and circulation in the Barents Sea

Dense water masses from Arctic shelf seas are an important part of the Arctic thermohaline system. We present previously unpublished observations from shallow banks in the Barents Sea, which reveal large interannual variability in dense water temperature and salinity. To examine the formation and circulation of dense water, and the processes governing interannual variability, a regional coupled ice-ocean model is applied to the Barents Sea for the period 1948-2007. Volume and characteristics of dense water are investigated with respect to the initial autumn surface salinity, atmospheric cooling, and sea-ice growth (salt flux). In the southern Barents Sea (Spitsbergen Bank and Central Bank) dense water formation is associated with advection of Atlantic Water into the Barents Sea and corresponding variations in initial salinities and heat loss at the air-sea interface. The characteristics of the dense water on the Spitsbergen Bank and Central Bank are thus determined by the regional climate of the Barents Sea. Preconditioning is also important to dense water variability on the northern banks, and can be related to local ice melt (Great Bank) and properties of the Novaya Zemlya Coastal Current (Novaya Zemlya Bank). The dense water mainly exits the Barents Sea between Frans Josef Land and Novaya Zemlya, where it constitutes 63% (1.2 Sv) of the net outflow and has an average density of 1028.07 kg m⁻³. An amount of 0.4 Sv enters the Arctic Ocean between Svalbard and Frans Josef Land. Covering 9% of the ocean area, the banks contribute with approximately 1/3 of the exported dense water. Formation on the banks is more important when the Barents Sea is in a cold state (less Atlantic Water inflow, more sea-ice). During warm periods with high throughflow more dense water is produced broadly over the shelf by general cooling of the northward flowing Atlantic Water. However, our results indicate that during extremely warm periods (1950s and late 2000s) the total export of dense water to the Arctic Ocean becomes strongly reduced.