2012年夏季北极浮冰生物群落结构及垂直分布特征研究

海冰生物群落是北极生态系统的重要组成部分,在北冰洋初级生产和碳循环中扮演着重要角色。本文利用荧光显微分析技术对2012年度夏季采集于北冰洋中心区的浮冰生物群落进行了分析,结果显示：柱总生物量平均为105.85±53.41 mgC •m^-2,其中细菌占生物量的47.2%,而后依次是硅藻（26.7%）,鞭毛虫（18.2%）,鞭毛藻（6.9%）和纤毛虫（1.0%）。最高纬站位（123°43.454′E 87°39.598′N）出现冰底鞭毛藻藻华现象,生物量可达329.6 μg C•L^-1,该站位生物群落处于硅藻藻华后期,海冰上层存在较大程度的融冰作用,底部冰芯营养盐N/P比较高,可能形成有利于鞭毛藻生长的小生境。与已有研究结果的对比表明,近年来夏季北极海冰的快速融化对浮冰生物群落结构产生了明显影响,异养类群生物量升高,细菌取代硅藻成为优势类群。     

2010年夏季白令海浮游细菌的多样性和群落组成分析

海洋浮游细菌在海洋生态系统的运行中起着关键性的生物地球化学作用。利用2010年夏季第4次北极考察获得的白令海不同深度水样,运用变性梯度凝胶电泳技术以及克隆建库等方法,来了解白令海中浮游细菌的多样性和群落组成等信息。结果表明:在白令海海盆区B07站位的50 m处,其浮游细菌的香农多样性指数是最高的,为2.61;香农多样性指数最低的是B07站位的3 m处,为1.99。白令海海盆区的细菌多样性变化比陆架区要大,有可能与海洋环境的复杂变化有关。通过克隆测序,鉴定出的浮游细菌类群分为4大类：α-变形杆菌、β-变形杆菌、γ-变形杆菌和拟杆菌。其中γ-变形杆菌所占的比例最大,为53%,是白令海中的优势种群;拟杆菌其次,为37%。这些浮游细菌在白令海中的分布情况为：γ-变形杆菌和拟杆菌存在于3个位点的所有水层中,α-变形杆菌只存在于B07站位的50m和100 m水层中,β-变形杆菌除B13站位的0 m处外,存在于其他站位的所有水层中。白令海B断面3个站位的温度随着深度的增加而降低,盐度随着深度的增加而升高。大体上白令海海盆区（B07站位）的硝酸盐、磷酸盐和硅酸盐浓度比陆架区（B15和B13站位）高,陆架区的铵盐浓度较海盆区高。     

农牧交错带不同土地类型土壤动物生态特征研究——以内蒙古卓资山为例

对内蒙古中部农牧交错带不同土地类型土壤动物进行研究,发现线虫占绝对优势,个体数占总个体数的64.95%.线虫个体数在不同土地类型的差异显著.线虫、蜱螨类和弹尾类构成研究区中小型土壤动物的优势类群.天然草地各生境土壤动物的类群数和个体数均高于撂荒地、半裸露坡地和裸露坡地.大型和中小型土壤动物的类群数和个体数的垂直分布具有表聚性.根据土壤动物聚类分析的结果,可将采样的6个生境分为3类:天然草地、人类干扰停止后自然恢复的坡地和裸露坡地.CCA排序表明土壤含水量对中小型土壤动物类群分布影响最大.土地利用方式相近的生境,土壤动物种类组成和个体数量相似程度较高.土壤动物组成的差异能够较好地反映土地类型的差异.     

准噶尔盆地东南缘绿洲荒漠交错带土壤动物群落特征

为理解准噶尔盆地东南缘绿洲-荒漠交错带土壤动物群落特征,采用国际通用采样方法在2010年4月、7月、9月及11月中旬对该交错带不同生境土壤动物群落进行了调查研究,比较分析了该区土壤动物群落组成、多样性及其季节动态特征。结果表明:①共采集到大、中小型土壤动物9 788只,隶属于4门12纲32目,其中甲螨目、弹尾目、中气门目和前气门目为优势类群,常见类群有垫刃目、鞘翅目幼虫、膜翅目、无气门目、缨翅目和双翅目幼虫,优势类群和常见类群占群落总个体数的96.27%,其他22类群均属于稀有类群,只占总捕获量的3.73%。②在不同生境土壤动物群落组成、个体数量及多样性都表现出了明显的时空变异（P<0.05）,其类群数高低顺序为自然林＞防护林＞牧草地＞灌木林＞耕地＞菜瓜地＞荒草原＞荒漠,而个体数量顺序为菜瓜地＞耕地＞牧草地＞防护林＞自然林＞荒草原＞灌木林＞荒漠。③不同生境土壤动物的垂直分布具有明显的表聚特征,即从地表向下,随着土壤深度的增加土壤动物个体数量逐渐减少。④在不同生境土壤动物个体数量表现出了明显季节变化,其高低顺序为冬季＞秋季＞春季＞夏季。研究结果为进一步开展干旱区绿洲-荒漠生态系统土壤动物生态学的研究奠定了基础。     

大兴安岭北部森林生态系统 大型土壤动物群落特征

对大兴安岭北部7个代表性森林群落进行了系统调查,总共获取大型土壤动物67类、6729只,隶属于4门7纲18目51科。其中,优势类群1类,常见类群10类,稀有类群56类。寒温带森林土壤动物生物量最大的类群为线蚓和蚯蚓,而温带森林土壤动物生物量最大的类群以蚯蚓为主。不同群落土壤动物的种类组成差异很大,通常群落的生境条件越优越,土壤动物的个体数量、种类越多。不同群落间个体数量、种类及生物量三者总的分布规律不完全一致,表现出生物群落组成特征的复杂性。各群落土壤动物多样性指数排序为:Ⅰ＞Ⅳ＞Ⅶ＞Ⅴ＞Ⅱ＞Ⅲ＞Ⅵ。土壤动物的个体数量、种类、生物量及多样性指数具有较明显的季节变化。     

太湖水生植物研究进展北大核心CSCD

自20世纪60年代以来,由于生境变化和人类活动干扰,太湖水生植物种类逐渐减少,已有伊乐藻(Elodeanuttallii)、水盾草(Cabomba caroliniana)和篦齿眼子菜(Potamogeton pectinatus)3种外来迁入物种出现;1960～2014年期间,太湖水生植物总生物量呈现单峰型变化,挺水植物生物量占水生植物总生物量的比例也同样呈现单峰型变化,而其它水生植物生物量占水生植物总生物量的比例则在持续增大;太湖水生植物群落的优势种也发生了变化,沉水植物群落的优势种由马来眼子菜(Potamogeton malaianus)和苦草(Vallisneria natans)变为仅为马来眼子菜。目前,对于太湖水生植物的研究,主要集中在水生植物的分布调查、光合特征、对富营养化水体的净化和重建水生植物群落、水生植物管理等方面,在太湖北部"藻型湖区"和太湖东北"草—藻过渡湖区"重建稳定且多样的水生植物群落,已经成为太湖水生植物研究的热点和难点。     

沙地柠条(Caragana)灌丛微生境节肢动物群落特征

以宁夏荒漠草原柠条（Caragana）灌丛林地为研究对象,于2011年春、夏、秋季,利用陷阱诱捕法,调查了灌丛微生境节肢动物群落分布特征。结果表明：（1）调查共获得节肢动物9目31科32个类群,分属于4种功能群（植食性、捕食性、腐食性和杂食性）。其中,优势类群为蚁科（Formicidae）和拟步甲科（Tenebrionidae）,个体数占总个体数的71.97%;常见类群有7科8个类群,个体数占总个体数的19.72%;其余22个类群为稀有类群,个体数仅占总个体数的8.30%。（2）随着季节变化,灌丛内外节肢动物类群组成和个体数分布均发生改变。春季灌丛内外均包括优势类群、常见类群和稀有类群;夏季灌丛内外均包括优势类群,而灌丛下仅有常见类群,无稀有类群,灌丛外既没有常见类群也没有稀有类群;秋季灌丛内外均有优势类群和常见类群,但灌丛内外均无稀有类群。（3）夏季灌丛内外共有类群数最少,相似性指数最低,秋季次之,而春季灌丛内外共有类群数最多,相似性指数也最高。（4）春季和秋季,灌丛内外微生境中节肢动物个体数、丰富度和Shannon指数均无显著差异（P>0.05）。夏季,节肢动物个体数灌丛内外无显著差异性（P>0.05）,但丰富度和Shannon指数均表现为灌丛内显著高于灌丛外（P<0.05）。（5）春季灌丛内外捕食性、植食性和杂食性节肢动物的个体数和丰富度均无显著差异性（P>0.05）;但是,腐食性动物个体数和丰富度均表现为灌丛内显著高于灌丛外（P<0.05）。夏季,仅有捕食性动物丰富度呈现出灌丛内显著高于灌丛外（P<0.05）,而其他指标灌丛内外均无显著差异性（P>0.05）。秋季,每种功能群动物的个体数和丰富度灌丛内外均无显著差异性（P>0.05）。沙地灌丛内外生境中节肢动物的空间分布,既与灌丛本身生理生态学特性相关,也与季节性降雨和温度等气象条件的改变密切相关。     

太湖水生植物研究进展

自20世纪60年代以来,由于生境变化和人类活动干扰,太湖水生植物种类逐渐减少,已有伊乐藻(Elodeanuttallii)、水盾草(Cabomba caroliniana)和篦齿眼子菜(Potamogeton pectinatus)3种外来迁入物种出现;1960～2014年期间,太湖水生植物总生物量呈现单峰型变化,挺水植物生物量占水生植物总生物量的比例也同样呈现单峰型变化,而其它水生植物生物量占水生植物总生物量的比例则在持续增大;太湖水生植物群落的优势种也发生了变化,沉水植物群落的优势种由马来眼子菜(Potamogeton malaianus)和苦草(Vallisneria natans)变为仅为马来眼子菜。目前,对于太湖水生植物的研究,主要集中在水生植物的分布调查、光合特征、对富营养化水体的净化和重建水生植物群落、水生植物管理等方面,在太湖北部"藻型湖区"和太湖东北"草—藻过渡湖区"重建稳定且多样的水生植物群落,已经成为太湖水生植物研究的热点和难点。     

2011年夏季北极王湾细菌群落结构分析及浮游细菌丰度检测

采用PCR-DGGE方法,对2011年夏季北极王湾表层海水及沉积物细菌的群落分析结果表明,沉积物中的细菌多样性指数高于海水。深水站位(S1和S3)的沉积物细菌群落不但与浮游细菌群落存在差异,并且与浅水站位(S5)也存在差异。位于湾口、湾内的浮游细菌群落组成也存在一定差异。测序结果显示,王湾海洋细菌的多样性组成包括α-变形细菌、γ-变形细菌、δ-变形细菌、放线菌、拟杆菌及厚壁菌等类群。基于定量PCR方法的检测结果表明,位于湾口、湾内的浮游细菌丰度相似,但湾内玫瑰杆菌支系的丰度明显低于湾口。研究结果表明,与湾口相比,王湾湾内的细菌群落受陆源性淡水输入的影响明显,不但表现在细菌群落的多样性组成上,也表现在某些特定细菌类群的数量分布上。     

大兴安岭不同冻土带沼泽和湿草甸土壤动物群落结构特征

2003年3月、6月和9月,对大兴安岭连续多年冻土带、岛状融区冻土带和岛状冻土带的沼泽和湿草甸土壤动物进行了调查研究.在这些沼泽和湿草甸选取了6个样地,共获得土壤动物17 647只,隶属于4门8纲19目.其中,大型土壤动物的优势类群为3类,分别是线蚓科、蚁科和正蚓科,常见类群为12类;中、小型土壤动物以弹尾类和蜱螨类为最多,它们约占总个体数的92.48％,优势类群为5类,分别是中气门亚目、甲螨亚目、前气门亚目、节跳虫科和摇蚊科,常见类群有3类.     

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     

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.     

南极中山站及毗邻地区湖泊与冰雪COD_(Mn)研究

在 CHINARE- 1 5考察期间对中山站及毗邻地区的湖泊和冰雪进行了采样。它们的CODMn指数与中国《地面水环境质量标准》相比 ,可分为三类 :一类水质所占比重最大 ,大约为56% ,二类和三类分别为 37%、7%。各类水体的 CODMn指数主要为自然源所贡献 ,人为污染不明显。湖水的 CODMn指数是生物生长状况、有机质含量、盐度和水体氧化还原程度的综合体现 ,新鲜降雪样的 CODMn指数指示了该地区的大气洁净度。     

南极中山站近岸海冰生态学研究 Ⅱ．1992年冰下水柱浮游植物生物量的季节变化及其与环境因子的关系

自１９９２年４月１２日至１２月３０日对中山站附近内拉峡湾冰下水柱中浮游植物生物量以及环境因子的季节变化进行了测定。水中叶绿素ａ含量在０．０３－２１．４０ｍｇ／ｍ３之间波动，在覆冰期间，生物量基本上随深度的增加而下降；５－９月份各层次的生物量普遍低于０．５ｍｇ／ｍ３，８－９月份低于０．１ｍｇ／ｍ３。各层次中以水表含量的季节变化最为明显，成冰后在９月份形成低谷，于１２月中旬紧接着冰底水华的消失而形成单一峰值。生物量中微型浮游植物（＜２０μｍ）的比重在４－９月份的多数层次占有一半以上，１０月份后随着生物量的上升而下降，在水华期水表的比重最低，仅占总量的３．２％。其柱总生物量基本上与冰中生物量处于同一数量级，在冰藻水华期其量值甚至低于冰中生物量。营养盐（μｍｏｌ／Ｌ）的波动范围为ＰＯ４－Ｐ：０．３２－０．７９，ＳｉＯ３－Ｓｉ：２６．４７－６９．９２，ＮＯ３－Ｎ：１．４１－３１．７５，尽管水华期水表营养盐含量降至观测期间的最低点，但仍能满足冰下浮游植物的生长所需。光辐照度由于在冰水界面的量值仅为冰表入射光的不足５．３％至低于１％，成为水中产量最为可能的限制因子。     

南极海冰区冰藻类群及兴衰过程

本文总结了国际上对南极冰藻类群及其生理生态特性的多年研究成果 ,结合我国科学家在南极长城站以及在戴维斯和中山站的越冬研究 ,阐述了南极海冰区的冰藻类群及其形成机理 ,对冰藻的形成、存活、旺发和消亡过程进行讨论 ,并对大洋浮冰区和近岸固定冰区冰藻类群的生态特性进行对比 ,提出了今后有待进一步深入研究的领域     

Photosynthetic characteristics of sinking microalgae under the sea ice

The photosynthetic characteristics of sinking a microalgal community were studied to compare with the ice algal community in the sea ice and the phytoplankton community in the water column under the sea ice at the beginning of the light season in the first-year sea ice ecosystem on the Mackenzie Shelf, in the western Canadian Arctic. The phytoplankton community was collected using a water bottle, whereas the sinking algal community was collected using particle collectors, and the ice algal community was obtained by using an ice-core sampler from the bottom portion of ice core. Photosynthesis versus irradiance (P-E) incubation experiments were conducted on deck to obtain the initial slope (α^B) and the maximum photosynthetic rate (P_m^B) of the three algal communities. The α^B and the P_m^B of the light saturation curve, and chlorophyll a (Chl a) specific absorption coefficient (ā_ph*) between the sinking microalgal community and the ice algal community were similar and were distinctly different from the phytoplankton community. The significant linear relationship between α^B and P_m^B, which was obtained among the three groups, may suggest that a photo-acclimation strategy is common for all algal communities under the low light regime of the early season. Although the sinking algal community could be held for the entire duration of deployment at maximum, this community remained photosynthetically active once exposed to light. This response suggests that sinking algal communities can be the seed population, which results in a subsequent phytoplankton bloom under the sea ice or in a surface layer, as well as representing food for the higher trophic level consumers in the Arctic Ocean even before the receding of the sea ice.     

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.     

Ice algae in the Barents Sea: types of assemblages, origin, fate and role in the ice-edge phytoplankton bloom

Ice algal accumulations were recognised by their vertical distribution in the ice, as surface, interior and bottom assemblages. The latter were quantitatively the most important in the Barents Sea and in particular the sub-ice assemblage floating towards, or attached to, the undcr-surface of the sea ice. Colonisation of the ice takes place by a "sieving" of the water between closely spaced platelets on the ice under-surface. Once associated with the ice, the assemblage undergoes a succession terminated by the dominance of ice specialists. In a horizontal S-N section through the ice, three distinct zones may be recognised: at the ice edge the recently colonised ice has a layer of algae up to a few millimeters in thickness consisting primarily of planktonic species. Further into older first year ice the algal layer becomes thicker and is typically dominated by the pennate diatom Nilzschia frigida Grunow. Below multi-year ice in the central polar basin decimetre-thick mats of algae are found, consisting almost exclusively of the centric diatom Melosira arclica (Ehrenberg) Dickie and a few associated, mostly epiphytic, species. The predominantly planktonic sub-ice assemblages at the ice edge can grow under stable conditions as soon as the light becomes adequate in the spring, and they are able to multiply actively for one to two months before planktonic growth is possible. The sub-ice plankton assemblage thus forms an inoculum released to the stabilising water when the ice starts melting. This may explain how a phytoplankton bloom can develop explosively at the ice edge as soon as the ice melting commences, at a time when the number of algal cells in the water column is still very low.     

The progress in the study of Arctic pack ice ecology

The sea ice community plays an important role in the Arctic marine ecosystem. Because of the predicted environmental changes in the Arctic environment and specifically related to sea ice, the Arctic pack ice biota has received more attention in recent years using modern ice-breaking research vessels. Studies show that the Arctic pack ice contains a diverse biota and besides ice algae, the bacterial and protozoan biomasses can be high. Surprisingly high primary production values were observed in the pack ice of the central Arctic Ocean. Occasionally biomass maximum were discovered in the interior of the ice floes, a habitat that had been ignored in most Arctic studies. Many scientific questions, which deserve special attention, remained unsolved due to logistic limitations and the sea ice characteristics. Little is know about the pack ice community in the central Arctic Ocean. Almost no data exists from the pack ice zone for the winter season. Concerning the abundance of bacteria and protozoa, more studies are needed to understand the microbial network within the ice and its role in material and energy flows. The response of the sea ice biota to global change will impact the entire Arctic marine ecosystem and a long-term monitoring program is needed. The techniques, that are applied to study the sea ice biota and the sea ice ecology, should be improved.