宁晋泊地区全新世温暖期以来气候与环境变化研究

宁晋泊沉积物的环境指标高分辨率分析,揭示了作新世温暖期以来气候变化规律和湖泊演化过程。全新世温暖期早期,气候温暖,降水丰沛,环境稳定,湖泊水草茂美;其中在５５００－６０００ａＢＰ有一个短暂的降温过程;温暖期晚期,气候波动明显。全新世晚期,气候呈规律性波动,与华北地区文史资料一致,具有良好的可比性。     

香港南部近海晚第四纪钙质超微化石分布及其地质意义

据香港南部近海５个工程钻孔中钙质超微化石的组合特征、分布规律、丰度及分异度等所揭露沉积层的地质时代，作者认为该区地层包括中更新统（上部）、上更新统和全新统。按钙质超微化石的古生态和沉积物特征，本区全新世的气候经历了升温期、温暖期两个气候期，温暖期中间存在两次降温，可能造成海平面下降。     

中国全新世气候变化研究进展

全新世气候变化研究是古气候研究的一个重点，中国全新世气候变化的研究也是全球变化研究中重要的一部分，大量的研究工作为恢复中国全新世气候做了在贡献。中国地形地貌复杂，又处在具有复杂时空变率的东亚季风控制范围内，这使得不同的研究工作者在一些问题上存在意见分歧，比较统计的意见是：中国全新世纪始于约10．5kaBP；在约9－8kaBP左右为一段降温期；7－4kaBP为一段温暖期，通常称之为全新世大暖期；大约3kaBP左右开始降温，至近代才又升温；约1300aA.D左右进入小冰期，到1850aA．D．左右结束，其间又有几次比较明显的温度振荡。1850aA.D.至今为温度的上升期。对于气候变动的驱动因素，不同的学者看法不一；从长时间尺度看，太阳辐射变化是气候变化的主要驱动力。     

青藏高原日土地区全新世中期以来介形类和孢粉组合变化及其古环境意义

本文综合分析了青藏高原日土地区RT-1剖面中介形类和孢粉种类组合的变化,结合三个光释光测年数据,探讨了该地区6510aBP以来古环境、古气候的演变。分析表明:日土地区在全新世中期曾有一个温暖湿润期(6170～5540aBP),之后气候环境频繁波动,逐渐趋向冷干,接近现代气候环境。43～30kaBP期间在鲁玛江冬错和班公错之间的古泛湖解体后,日土地区因为地势低洼,而在当时成为一个封闭的水体,并且一度与相邻的班公错相连。当时的水体一直持续到全新世,在经历了全新世暖湿期时短暂的湖涨期以后,逐渐萎缩,至约1570～1380aBP最终干涸消失,形成现今地貌。研究表明全新世大暖期在本地区也有反映,但是在高原深部,大暖期更为短暂,气候波动更为频繁。     

香港南部近海第四纪钙质超微化石分布及其地质意义

据香港南部近海5个工程钻孔中钙质超微比石的组合待征、分布规律、丰度及分异度等所揭露沉积层的地质时代,作者认为该区地层包括中更新统(上部)、上更新统和全新统。按钙质超微化石的古生态和沉积物特征,本区全新世的气候经历了升温期和温暖期两个气候期,温暖期中间存在两次降温,可能造成海平面下降。(中文全文见:南海地质研究(七).武汉:中     

西藏昌都崩勒溶洞石笋7 ka BP以来高分辨δ18O、δ13C记录的气候变化

通过对青藏高原崩勒溶洞石笋进行高精度的230 Th测年和C、O同位素分析,建立了中全新世7ka BP以来西藏昌都地区高分辨率的古气候变化记录。石笋C、O同位素记录揭示出,西藏昌都地区中全新世(约7ka BP)以来的气候演化大致可分为3个气候阶段:7000~4500aBP为暖期阶段,气候总体处于高温暖湿,伴随缓慢降温;4500~2300aBP为降温期阶段,出现持续降温,气候变得干旱;2300aBP至今为升温期阶段,气温及降水均出现波动上升。石笋C、O同位素记录的研究结果表明,中全新世以来研究区存在高温暖湿、快速降温干旱以及后期气候强烈震荡升温的气候过程。通过与董歌洞石笋同位素记录对比表明,崩勒溶洞石笋δ18 O同位素曲线变化的斜率、震荡幅度都要明显高于董歌洞石笋记录,揭示出青藏高原东部季风区的气候波动与全球性冷暖变化具有一致性,但高原石笋同位素记录对气候变化更加敏感。昌都石笋同位素反映的气候变化趋势与低纬地区夏季太阳辐射强度变化正相关,表明太阳辐射强度变化是高原季风影响区气候变化的重要驱动因素。     

粘土矿物在黄河源区古气候研究中的应用

沉积物中粘土矿物的组成具有一定的古气候指示意义。利用沉积物中粘土矿物的组成探讨了黄河源区全新世的古气候变迁。通过X衍射方法分析了一个全新世地层剖面的粘土矿物类型和含量的变化,这些粘土矿物主要由伊利石、伊蒙混层矿物和少量的高岭石、绿泥石组成。对粘土矿物含量变化的分析和对比研究表明,黄河源区在全新世的气候寒冷干燥,即使在大暖期也显得温凉。全新世的气候演变可划分为3个阶段,即早全新世的干冷期、中全新世的温凉期(大暖期)和晚全新世的干冷期。在大暖期,在7 0kaB P 和5 0kaB P 前后发生了两次较强的降温事件。     

桂林响水洞600kaBP以来石笋高分辨率的气候记录

通过对桂林响水洞的石笋进行高精度的TIMS—U系测年和C、O同位素分析，建立了中全新世6．00ka B P以来桂林地区高分辨率的古气候变化时间序列。石笋剖面的C、O同位素记录揭示，桂林地区中全新世(6．00ka B P)以来的季风气候变化，大致可分为2个气候期：6．00～3．57ka B P为气候适宜期，显示东亚夏季风由强盛逐渐变为减弱的趋势，为气候温暖湿润期；3．57～0．37ka B P为降温期，显示东亚夏季风减弱，冬季风增强以及气候的大幅度波动。在这一降温期，间夹多次短暂的温暖期。石笋同位素记录的研究结果表明，在6．00～0．37ka B P间的中全新世——气候适宜期，δ^18O值由偏负逐渐向偏正的变化趋势，反映东亚夏季风由强变弱，降雨由多变少，气温由高变低的变化趋势。     

中国全新世气候演变研究的进展

全新世是与人类关系极为密切的一个时期分析,分析,总结了我国科学家对这一时期气候演变的研究成果,并对这些成果进行了讨论。我国全新世约从１０ｋａ 时间气候波动激烈,了大暖期,隋唐温暖期,小冰期等典型时期各时期内有部分     

青藏高原东北部黄河源区大暖期气候特征

本文通过孢粉、有机碳和粘土矿物的分析,探讨了黄河源区全新世的气候变迁,重点论述了大暖期的气候特点。在全新世,黄河源区的气候总体凉干,属于高原的高寒气候。在大暖期,该区的气候较现今高2～3℃,显得湿润些,但波动较频繁,尤其是大暖期的后期波动剧烈,并在5．0kaBP前后发生一次剧烈的降温。记录表明,黄河源区的大暖期始于9．0kaBP,止于2．30kaBP,较我国其他地区开始得早,而结束得晚,其鼎盛时期为6．0kaBP前后。     

末次冰期以来中国自然环境变迁及其与全球变化的关系

末次冰期我国西部的冰川长度比现代冰川长2—5倍,雪线低300—1080m;东部多年冻土区南界在33°20′—33°40′N,青藏高原多年冻土区东北部的下界在海拔2200—2600m 处;黄、东海海平面下降130—155m;经向环流加强,北方冷空气增强。末次冰期以后冰川阶段性退缩,多年冻土区阶段性缩小,海平面间歇性上升;8000—6000aB.P.为高温期,出现2—5m 高海面,5600—5000aB.P.气温短暂下降,海平面突然回落,冰川有所前进;3000aB.P.的新冰期和15—19世纪的小冰期,气候、冰川和海平面都有显著变化。哺乳动物的绝灭和迁徙是自然和人为双重影响的结果。这些变化都是全球变化的表现。     

渤海湾西岸现代岸线钻孔记录的全新世沉积环境与相对海面变化

以渤海湾西岸现代岸线附近的NP3、CH110和BT113三个钻孔全新世岩心为研究对象,采用沉积岩石学、AMS ¹⁴C(accelerator mass spectrometry ¹⁴C,加速器质谱¹⁴C)测年、微体生物聚类分析等方法精细判别沉积相,重建渤海湾西岸全新世沉积演化历史,并利用微体生物组合分带对水深变化的指示,定量讨论全新世相对海面变化。结果表明:渤海湾西岸全新世受海陆交互作用影响,经历了沼泽-潮滩-浅海-前三角洲-三角洲前缘-三角洲平原环境的演化过程。全新世初始阶段,研究区中部和北部发育沼泽环境,南部未见沉积,与上更新统河流相沉积呈不整合接触。全新世早期,研究区潮滩环境发育。潮滩层厚度约1 m,历时数百至1千余年。至7000 cal BP前后水深增大,研究区进入浅海环境。约6000 cal BP,沿岸南北两端先后进入三角洲过渡环境,中部三角洲环境约开始于1500 cal BP。渤海湾西岸地区全新世的环境演化同时记录了该地区的相对海面变化:约10000 cal BP前后,渤海湾相对海平面已接近21.3~20.4 m。约8000 cal BP,相对海平面介于18.6~17.0 m。约6000 cal BP时相对海平面低于6.8 m,5000~1000 cal BP,相对海平面高于-2.5 m,1000~800 cal BP,相对海平面介于-1.3~-0.4 m。8000~5000 cal BP时,相对海面上升约15.0 m,上升速率达5 m/1 ka。     

晚更新世以来中国海平面的变化

在我国漫长的海岸和陆架海的岛围至今保存着许多形态完好的海蚀地形、海相沉积及各种海洋生物的遗迹、遗体。近年来在大陆架海底调查中,声学探测和海底取样结果也证实广阔的大陆架海底保留不少代表古海岸带的残余沉积、地形。     

Multiple glaciations and marine transgressions, western Kennedy Channel, Northwest Territories, Canada

Along a 70 km section of western Kennedy Channel three prominent weathering zones are identified and serve to differentiate major events in the Quaternary landscape. The oldest zone (Zone 111b) is characterized by a deeply weathered, erratic-free terrain which extends from the mountain summits down to ca. 470 m above sea level. This zone shows no evidence of former glacierization. Zone 111a extends from ca. 470 to 370m above sea level and is characterized by sparse granite, gneiss and quartzite erratics amongst weathered bedrock and extensive, oxidized colluvium. The Precambrian provenance and uppermost profile of these erratics reflect the maximum advance of the northwest Greenland Ice Sheet onto northeastern Ellesmere Island. These uppermost erratics along western Kennedy Channel decrease in elevation southward and suggest that the former Greenland ice was thickest in the direction of the major outlet of Petermann Fiord. No evidence of a former ice ridge in Nares Strait was observed. Zone II is marked by the moraines of the outermost Ellesmere Island ice advance which form a prominent morpho-stratigraphic boundary where they cross-cut the zone of Greenland erratics at ca. 250–350 m above sea level. These moraines show advanced surface weathering and ice recession from them is associated with a pre-Holocene shoreline at 162 m above sea level. Late Wisconsin/Würm glacial deposits, equivalent to Zone I, were not observed in the lower valleys bordering Kennedy Channel. The outermost Ellesmere Island ice advance (Zone II) is radiometrically bracketed by ¹⁴C dates on in situ shells from subtill and supratill marine units which are 40,350±750 and>39,000 B.P., respectively. Amino acid age estimates on the same shell samples and others from similar stratigraphic positions all suggest ages of >35,000 B.P. Stratigraphically and chronologically this ice advance is correlated with the outermost Ellesmere Island ice advance 20–40 km to the north which formed small ice shelves when the relative sea level was ca. 175 m above sea level. The Holocene marine transgression along western Kennedy Channel occurred in an ice-free corridor maintained between the separated margins of the northwest Greenland and northeast Ellesmere Island ice sheets during the last glaciation. Initial emergence may have begun ca. 12,300 B.P., however, sea level had dropped only 15 m by ca. 8000 B.P. after which glacio-isostatic unloading of the corridor was rapid. The implications of these data are discussed in the context of existing models on high latitude glaciation and paleoclimatic change     

西藏阿里阿伊拉日居山脉第四纪冰川作用

在西藏阿里阿伊拉日居山脉南北两麓及切割山脉的各沟谷中,分布着4套早更新世以来的冰川沉积物。根据这些冰川沉积物的地层层序和冰川沉积物的电子自旋共振(ESR)年龄测定结果,将阿伊拉日居山脉南北两麓所发生的4次早更新世以来的冰川作用,分别命名为札达冰期(1161-952 ka BP)、阿伊拉日居冰期(762-730 ka BP)、学朗冰期(336-211 ka BP)和弄穷冰期(105-15 ka BP),并与青藏高原及其他地区冰期进行了对比。各次冰期的冰川性质分别为大型山岳冰川、冰帽、山麓冰川和中小型山谷冰川。全新世时期,现代冰川有过冰川推进。近期冰川则发生了明显的后退。     

Glacial history of the Spitsbergen archipelago and the problem of a Barents Shelf ice sheet

The popular concept of a Late Weichselian ice sheet covering the Barents Shelf and confluent with the Scandinavian and Russian ice sheets is based primarily on the 6500 B.P. isobase which rises to the east over Spitsbergen, and to the west over Franz Joseph Land. Analysis of uplift curves from the Spitsbergen archipelago shows, however, that the strongest early Holocene uplift occurs over northeastern Spitsbergen and eastern Nordaustlandet, falling both to east and west, and that the centre of uplift migrates to the southeast during the Holocene. Direct evidence of glacier fluctuation indicates an important Billefjorden Stage of glaciation at about 11,000 to 10,000 B.P., part of whose extent can be defined by moraines and by abrupt changes in the marine limit. The dominant ice masses of the Billefjorden Stage seem to have formed over eastern Spitsbergen, Edgeøya, Barentsøya and southern Hinlopenstretet, and it is the decay of this ice mass which is primarily responsible for the pattern of early Holocene uplift. Stratigraphic evidence suggests the absence of an important glacial event at 18,000–20,000 B.P., but an important phase of Spitsbergen-centred glaciation at about 40,000 B.P., and a glacial phase at 80,000–120,000 B.P. It is suggested that many raised beach sequences outside the Billefjorden readvance show an upper sequence related to deglaciation at about 40,000 B.P., and a lower, Holocene sequence related to decay of the Billefjorden ice. The anomalous pattern of late Holocene uplift may be related to restrained rebound produced by regeneration of ice on the main islands of the archipelago and unrestrained rebound on Hopen and Kong Karls Land, which were incapable of sustaining large ice masses of their own. A pattern of LateGlacial climatic circulation which may have produced ice masses on the east coast of Spitsbergen, west coast of Novaya Zemlya and north coast of Russia is suggested. It is also suggested that this pattern of glaciation produced features which have been wrongly interpreted as evidence of a Barents ice sheet.     

一条Rodinia山脉——震旦纪的喜马拉雅山

笔者首次将海拔高度的概念及现代冰川理论 ,并结合古地磁资料 ,提出罗圈冰期时古天山 -秦岭山脉是一条大约位于赤道 -北回归线之间、由众多高山组成的 ,且许多山峰至少在 4 0 0 0m以上 ,已形成冰川、或许局部地区存在冰原的山脉 ,总的地理特征类似于今天的喜马拉雅山脉。而华北地块和库鲁克塔格地块是高原或平原 ,此二地块的南边是海域。古秦岭的南坡是现代秦岭的北坡。冰川融化时冰水携带的冰碛物向南流入海 ,所以华北地块上无冰碛物存在大地构造上 ,晋宁期以前 ,上述各地块相互独立。震旦纪时它们开始发生作用 ,秦岭地块和阿克苏—乌什地块分别向华北地块与库鲁克塔格地块汇聚 ,引起后者上升 ,逐渐发展成为山脉。至震旦纪末期 ,山脉上升到 4 0 0 0m以上 ,形成冰川。此后 ,山脉被剥蚀夷平 ,至寒武纪初 ,华北、库鲁克塔格两地块又降到海平面之下接受沉积 ,该山脉消亡。由此我们恢复了新元古代超大陆一条造山带 ,并推测新元古宙末期华北、华南、塔里木三大地块曾经汇聚在一起     

Glaciation in northern East Greenland during the Late Weichselian and Early Flandrian

The frontal positions of glaciers in fiords, sounds and larger valleys during the glaciation maximum around 10,000 B.P. and the extent of ice-free areas at that time are shown, together with an isobase map of the altitude of the contemporaneous (or younger) marine limit. A number of ¹⁴C and some Amino Acid datings related to the glacial advance, culmination and retreat are presented. Some time after a Middle Weichselian period with restricted glaciation the glaciers advanced and stood at their maximum positions at about 10,300 B.P., in some areas remaining there until about 9500 B.P., at which time sizeable lowland areas outside the ice-fronts were unglaciated and a large number of nunataks of various types occurred. The retreat of the glaciers started about 10,300 B.P. in the south, but seems to have been delayed towards the north. However, by 9000 B.P. all outer parts of the fiords were deglaciated and their central parts by 8500 B.P. The marine limit synchronous with this glaciation maximum and the deglaciation sinks from a southern maximum value of about 110 m to about 55 m in the north, reflecting a decreasing amplitude of the glacial advance.     

Glacial history and marine environmental change during the last interglacial-glacial cycle, western Spitsbergen, Svalbard

Superimposed glacial and marine sediment exposed in coastal cliffs on Brøggerhalvøya, west Spitsbergen, contain four emergence cycles (episodes D, C, B, and A) that are related to glacial-isostatic depression and subsequent recovery of the crust. Tills are found in episodes C and B; in each case glaciation began with an advance of local glaciers, followed by regional glaciation. The marine transgression following episode C deglaciation reached 70 to 80 m above sea level. Glacial-marine and sublittoral sands within episode C contain a diverse and abundant microfauna requiring marine conditions more favorable than during the Holocene. We define this interval as the Leinstranda Interglacial. Based on the fauna, sedimentology and geochronology (radiocarbon, amino acid racemization, and uranium-series disequilibrium) we conclude that the Leinstranda Interglacial occurred during isotope substage 5e. Episode B deglaciation occurred late in isotope stage 5 (c. 70 ± 10 ka ago), and was followed by a marine transgression to about 50 m above sea level. The associated foraminifera, mollusca, and vertebrate fauna require seasonally ice-free conditions similar to those of the Holocene, but less ameliorated than during the Leinstranda Interglacial. A significant influx of Atlantic water into the Norwegian Sea, augmented by a local insolation maximum late in isotope stage 5, are required to produce shallow-water conditions similar to those of the Holocene. There is no evidence for major glacial activity during the Middle Weichselian (isotope stages 4 and 3), and we conclude that ice margins were not significantly different from those of the late Weichselian, but the record for this interval is scant. The extent of ice at the Late Weichselian maximum was less than during either of the two preceding episodes (B or C). Late Weichselian deglaciation (episode A) began prior to 13 ka B.P. Oceanic and atmospheric circulation patterns conducive to large-scale glaciation of western Spitsbergen are not well understood, but those patterns that prevailed during isotope stages 4,3, 2, and 1 did not produce a major glacial advance along this coast.     

早全新世季风演化的高分辨率石笋δ18O记录研究--以河南老母洞石笋为例

基于豫西老母洞LM2石笋8个高精度230Th年龄,449个氧碳同位素,建立了达十年际分辨率的8.2~10.9 ka B.P.亚洲季风变化的δ18O记录序列.老母洞石笋δ18O值最为偏负达-12.0‰,最偏正为-8.2‰,振幅达3.8‰.早全新世10.13~10.9 ka B.P.时段内,河南西部老母洞石笋和东石崖石笋,陕西九仙洞C996-2石笋δ18O曲线揭示该时段内季风稳定,而中国南方的衙门洞石笋、三宝洞石笋和极地冰芯GRIP记录揭示该时段季风逐渐增强;同时季风达到顶峰的时期也不相同,进一步说明中国南北方早全新世10.13~10.9 ka B.P.时段季风演变过程的差异,可能与中国南北方气候的响应机制有关.从早全新世平均分辨率10年的LM2石笋记录中识别出8.2 ka,9.5 ka,10.2 ka和10.9 ka显著弱季风事件,尤其是8.2 ka和9.5 ka事件.对比分析老母洞与已发表的高分辨率石笋δ18O记录发现:石笋所揭示的某些冷事件发生时间在亚洲季风区存在差异,主要表现在事件内部变化特征及趋势上.LM2石笋δ18O曲线并没有明显记录9.3 ka弱季风事件,而是在9.3~9.6 ka B.P.左右记录了一个弱季风事件,与DSY09(2009)、Y1、HS-4记录相似,表明在该时段内存在季风的减弱事件,但是氧同位素传输的复杂性,使其在南北方表现不同.此外,在LM2石笋δ18O的8.2 ka B.P.开始时段,氧同位素曲线阶段性下降,且变幅达3‰,与Zhang等研究万象洞石笋提出的“中国8 200阶段”吻合,表明中国北方地区的8.2 ka事件是阶段性的事件,而南方的石笋氧同位素记录揭示的8.2 ka事件并未表现出阶段性特征,其原因有待于更多北方高精度石笋记录来进一步研究.LM2石笋氧同位素记录进行功率谱分析发现:在短尺度上季风变化与太阳活动密切相关,这与近年来对早全新世极端气候变化研究的驱动机制是一致的,早全新世亚洲季风的演化与太阳活动变化引起的太阳辐射能量的变化和北半球高纬气候的变化状况有关.