欧亚大陆中北部末次盛冰期以来的湖泊水位变化及其古气候指示意义

湖泊水位高低通常能有效地指示湖盆内湿润条件的变化,进而反映区域有效降水（降水—蒸发）变化,成为重建第四纪古气候演变的重要指标之一。通过对苏联和蒙古国古湖泊数据库以及中国晚第四纪古湖泊数据库中149个湖泊水位变化资料的梳理总结,探讨了末次盛冰期（18 cal. ka BP）以来该地区干湿变化规律及区域分异。根据研究区气候特征、地理位置及已有研究成果将其分为东欧湖泊区、中东亚干旱区和中国北方季风区三大湖区。根据不同水位记录在整个湖泊历史中出现的频率,采用3级重新分类区分出高、中、低3级水量,并把每个湖泊数字化的3级古水量表示成与现代的差值,得到每个湖泊样点每千年时间间隔内相对现代的5级水量变化（很湿润、湿润、无变化、干旱和很干旱）。结果表明,三大湖区末次盛冰期以来可能经历了不同的干湿变化过程：东欧地区湖泊水量记录在晚冰期之前较少,至全新世逐渐增多,且基本表现为早全新世干旱、中晚全新世相对湿润的状况。中东亚干旱区整体呈现出末次盛冰期至中全新世均较湿润而晚全新世干旱的气候状况,但区域内部不同湖泊在起讫时间和强度上存在显著差异。中国北方季风区的湿润期主要发生在早中全新世,但是不同湖泊有所不同。对比分析显示,早全新世时东欧地区东部气候随着斯堪的那维亚冰流的逐渐消退而逐渐变湿润,中全新世由于夏季北欧反气旋东翼的气旋气流增强而达到最湿润状态,西部地区早全新世由于强劲的西伯利亚热高压存在而整体偏干旱,中全新世由于夏季亚洲季风的渗透而转为湿润。中东亚干旱区冰期内的湿润条件可能主要与西风带降水及低温低蒸发有关,而全新世则可能主要与夏季风深入内陆导致降水增加有关。中国北方季风区全新世湿度变化可能主要受东亚季风控制。     

青藏高原湖泊沉积物对古气候环境变化的响应

随着全球变化研究的不断深入,青藏高原湖泊沉积物的研究得到很大发展。作为高分辨率古环境变化的“记录仪”,湖泊沉积物在重建晚第四纪全球环境变化中具有特殊的地位和意义。湖泊沉积物中储存的各种信息反映了矿物学、同位素地球化学、生物学、沉积学等方面对气候环境变化的响应。在古环境变化研究中,湖泊沉积物已经从定性化研究逐渐过渡到定量化研究。     

湖泊碳酸盐在过去环境变化研究中的应用

国内外的研究成果表明,湖泊沉积碳酸盐矿物及其微量元素、同位素分布特征记录了全球或区域古气候环境演变历史,可以从中提取大量定量化的古气候参数。因此,可以根据湖泊碳酸盐矿物的含量和碳、氧同位素变化等信息推知其形成时期的气候环境,重建古环境,揭示气候环境演变的规律。湖泊碳酸盐是一种研究古环境演化重要的代用指标,在过去气候环境变化研究中有广阔的应用前景。     

青藏高原湖泊沉积研究及其进展

青藏高原湖泊沉积研究主要围绕青藏高原隆升和全球变化响应开展的。研究揭示了青藏高原隆升具有整体性、阶段性和后期加速性。中晚更新世以来和末次间冰期-冰期气候演化过程得到重建,并能够与冰芯和深海氧同位素记录对比;同时也存在M IS3阶段强烈暖湿和末次冰盛期冷湿等区域特征;新仙女木事件在湖泊沉积物也有明显记录。全新世研究表明青藏高原早期暖湿并经历冷事件,大暖期普遍出现高水位,后期气候向干冷化方向发展。湖泊沉积环境定量化重建也得到研究。青藏高原湖泊沉积应在高分辨率纹层沉积和环境指标定量分析基础理论方面加强研究。     

青藏高原湖泊沉积研究及其进展

青藏高原湖泊沉积研究主要围绕青藏高原隆升和全球变化响应开展的。研究揭示了青藏高原隆升具有整体性、阶段性和后期加速性。中晚更新世以来和末次间冰期一冰期气候演化过程得到重建,并能够与冰芯和深海氧同位素记录对比;同时也存在MIS3阶段强烈暖湿和末次冰盛期冷湿等区域特征;新仙女木事件在湖泊沉积物也有明显记录。全新世研究表明青藏高原早期暖湿并经历冷事件,大暖期普遍出现高水位,后期气候向于冷化方向发展。湖泊沉积环境定量化重建也得到研究。青藏高原湖泊沉积应在高分辨率纹层沉积和环境指标定量分析基础理论方面加强研究。     

末次冰消期以来中国湖泊沉积记录的古气候演化及其驱动机制研究

末次冰消期是全球气候与环境出现较大变化的时段,其间发生了一系列气候突变事件,在全球不同地区以不同方式回应着这些事件的变化过程。综述了末次冰消期以来青藏高原高寒干旱区、西北干旱区、云贵高原湿润区以及东部平原地区的湖泊沉积记录的古气候演化特征,探讨了气候变化的驱动机制,并提出未来该研究领域亟待深入开展的工作,包括拓展高分辨率湖泊沉积记录的气候演化时间序列研究,提升学科交叉和与其他地质记录的对比研究,加强中国第四纪湖泊数据库和全球气候变化研究,以及加强水汽来源示踪研究。     

柴达木盆地东缘晚更新世气候变化的（古）土壤发生记录

柴达木盆地东缘典型剖面（古）土壤及其黄土线质的宏观特征和理化分析表明,本区晚更新世以来气候曾有几次较大的波动,反映了全球冰量影响的气候波动以及东亚季风气候的强弱变化特征。揭示出气候变化过程中温度和降水并不同步,温度主要受地球轨道变化引起的太阳辐射的影响;降水则主要取决于冬、夏季风的浊弱对比关系,夏季风盛行时,降水丰沛。间冰段古土壤Ｓｍ的土壤发生特征和强度,揭示了除低温引起的蒸发减少外,降水丰沛也是     

青海湖湖东沙地河湖-风成沉积记录的中晚全新世以来环境变化

青海湖盆地因其独特的地理位置和气候环境,对气候变化响应敏感,是研究环境变化重要的场所。本研究在青海湖湖东沙地获取两个剖面,采用AMS¹⁴C测年,结合岩性、粒径组分和常量元素氧化物及其比值等多指标分析方法,重建了湖东沙地8.4 ka BP以来的环境演变过程。结果表明：除少量沉积物处于中等化学风化阶段外,大部分沉积物处于物理风化和初级化学风化阶段,说明自8.4 ka BP以来研究区气候环境总体上相对寒冷干燥。在千年尺度上,研究区不同时间段的气候环境存在较大的差异。8.4—4.2 ka BP气候相对温暖湿润;其中,8.4—6.2 ka BP河湖相和风成相沉积互层,表明存在明显的百年尺度气候波动;6.2—4.2 ka BP化学风化和淋溶作用较强,表明季风降水较多,径流较强,发育了较为稳定的湖泊沉积环境。4.2 ka BP以来湖泊消失,化学风化和淋溶作用减弱,沉积物从砾石转变为砂质黄土,显示气候较为冷干且波动较大。对比分析表明,中晚全新世以来青海湖湖东沙地的气候变化特征与东亚季风边缘区其他区域基本一致,并主导了区域沉积环境的演变过程。     

1972-2012年青藏高原中南部内陆湖泊的水位变化

青藏高原的湖泊水位变化能够清晰的记录湖泊波动,分析近几十年来气候变暖背景下青藏高原典型湖泊水位的动态变化,对理解全球变化的区域响应特征和规律有重要意义。本文利用多源遥感数据,获取1972-2012年青藏高原南部地区5个典型湖泊的面积与水位序列,并分析了40年来湖泊水位的变化特征。研究结果表明,1972-2012年,普莫雍错,塔若错,扎日南木错水位呈上升趋势,分别上升了0.89 m、0.70 m、0.40 m;同期,佩枯错与玛旁雍错的水位呈下降趋势,分别下降了1.70 m、0.70 m。总体来看,五个湖泊在1990s-2012年的变化比1970s-1990s的变化更剧烈,从空间变化看,处于青藏高原边缘地带的佩枯错与玛旁雍错发生的变化呈现一致性,而位于中部地带的塔若错与扎日南木错的变化也呈现一致性。     

青海湖碳酸盐氧同位素环境记录再认识

青海湖是我国内陆最大的闭流型水体,地处东亚季风和西风的交汇影响区,对区域降水的改变等气候变化反应敏感,其水位变化历史是研究区域季风环境演变极其宝贵和重要的环境档案。青海湖Q14B孔岩芯介壳δ18Oc变化曲线自1991年发表以来,受到国内外同行的广泛关注和继续探讨。依据近年来青海湖气候与环境演变研究的最新研究结果和个人对闭流型湖泊同位素地球化学的认识,对介壳δ18Oc变化曲线进行了重新判读并得出以下结论:14.5~10.5 ka B.P.,青海湖区气候已逐渐从干冷向温湿过渡,季风降水逐渐增加;10.8~10.5 ka B.P.,青海湖处于碳酸盐滩湖环境,湖水深度从几米演变到接近干涸;10.5~9.5 kaB.P.,季风降水增加;9.5~8 ka B.P,湖水位从此前的接近干涸演变到此间的2~8 m,δ18Oc值跌落到一个较低的位置;8~3.5ka B.P,气候条件相对稳定,湖水不断蒸发引起重同位素的富集;3.5~0ka B.P,湖水处于同位素稳定阶段。研究结果还显示,δ18Oc值的短期波动与湖泊水位短期变化关系密切且明显,即水位高低分别对应δ18Oc的低值与高值。δ18Oc值的长期变化与湖泊水位长期变化关系不明显,水位较浅时,二者几乎无关联;水位较深时,水位的长期缓慢下降自然会导致δ18Oc逐渐攀升,而水位的长期缓慢上升也可以伴随δ18Oc逐渐攀升。     

末次盛冰期以来中国湖泊记录对环流系统及气候类型的响应

为了探讨中国长时间尺度湖泊时空演变规律和潜在的驱动机制,本文在柯本气候分区和中国季风—非季风区的划分基础上,对中国34个有明确数据的典型湖泊运行CCSM 3.0气候模拟系统和水量能量平衡模型模拟其水位变化,同时利用NCEP/NCAR再分析资料对中国按水汽输送划分的季风区进行验证。结果表明,末次盛冰期以来中国湖泊演化主要受千年尺度大气环流的驱动影响,在各个柯本气候区内没有明显的规律性。末次盛冰期以来,在季风区中国湖泊演化主要有早中全新世湖泊水位相对较高以及末次盛冰期和早全新世湖泊水位均较高2种演变规律;在东亚干旱区主要有中晚全新世期间湖泊水位相对较高以及末次盛冰期和中全新世湖泊水位均较高2种演变规律。本文为中国过去气候变化及湖泊演化机制研究提供新的证据,同时为人类全面认识末次盛冰期以来湖泊水位变化提供了新的视角。     

中全新世暖期与未来气候变暖情景下东亚夏季降水变化相似型分析

利用中全新世暖期和21世纪末期的多模式气候模拟资料,对这两个时期东亚地区夏季降水变化相似型进行分析。结果表明,东亚地区中全新世与21世纪末气候变暖情景下的夏季降水变化分布型存在一定的相似性,尤其反映在两个关键区上:青藏高原南部降水变化均出现增多,增幅达到1.5 mm/d以上;新疆西南部降水变化均出现减少,减少幅度达到0.1 mm/d以上,且中全新世降水模拟变化结果与地质气候记录定性吻合。因此东亚地区全新世暖期夏季降水变化在一定程度上可作为未来夏季降水变化的历史相似型。     

黄河源玛曲段全新世风成黄土-古土壤序列风化成壤特征以及古气候演变

通过对青藏高原东北部黄河源开展广泛细致的野外考察,选择位于玛曲段黄河左岸第二级河流阶地（T2）之上,赋存典型风成黄土-古土壤序列的达尔琼东（DEQ-E）剖面进行系统采样。在室内对采集样品进行了磁化率、烧失量、吸湿水、粒度、土壤微形态、地球化学元素和光释光（OSL）测年等综合分析,结论表明：(1)黄河源玛曲段DEQ-E剖面地层序列由上至下依次为现代草甸土层（MS）-全新世中期古土壤层（S0）-全新世早期过渡性黄土层（Lt）-阶地漫滩相沉积层（T2-al）;(2)黄河源玛曲段DEQ-E剖面风成黄土-古土壤序列风化成壤强度呈现出全新世中期古土壤层（S0）>全新世早期过渡性黄土层（Lt）>现代草甸土层（MS）的变化特征;(3)黄河源全新世的古气候演变可分为3个阶段：全新世早期（11000 a BP—9000 a BP）,西风势力减弱,东亚夏季风逐步增强,气温趋于变暖,降水有所增加;全新世中期（9000 a BP—3100 a BP）,东亚夏季风作用强盛,气候整体温暖湿润;全新世晚期（3100 a BP以来）,东亚夏季风衰退,西风势力有所增强,导致气候转向干冷。该研究成果有助于理解青...     

中国内陆区湖泊沉积所反映的全新世干湿变化

湖泊沉积记录的环境演变是全球变化的重要研究领域之一,通过对中国内陆区中30 个湖泊研究成果的总结和梳理,探讨了全新世以来该地区干湿变化的规律和区域分异。通过降水量结合传统分区方法将中国内陆区分为西北干旱区、东亚季风边缘区和青藏高原区。对每个湖泊样点以500 年为时间间隔,以孢粉为主要干湿指标,综合氧同位素、有机质及碳酸盐等,将湖泊干湿状况划分3 个干湿等级（干旱,半湿润,湿润）,建立区域干湿指数。结果表明,中国内陆不同区域全新世可能经历了不同的干湿变化过程：①西北干旱区基本上是早中全新世干旱,中晚全新世相对湿润,但区域差异明显;②东亚季风边缘区早全新世早期干旱,早全新世晚期和中全新世相对湿润,晚全新世干旱;③青藏高原区的湿润时期主要发生在早中全新世,但是不同地区有所不同。对比分析显示：西北干旱区的干湿变化可能受西风环流控制,但在时间和强度上区域内部差异较明显;东亚季风边缘区可能主要受东亚季风控制;青藏高原地区早中全新世的湿润可能与印度季风的增强相关。     

Holocene lake carbon sequestration,hydrological status and vegetation change,China

Lakes have received considerable attention as long-term sinks for organic carbon(C) at regional and global scales. Previous studies have focused on assessment and quantification of carbon sinks, and few have worked on the relationship between millennial-scale lake C sequestration, hydrological status and vegetation, which has important scientific significance in improving our understanding of lake C stocks and storage mechanisms. Here, we present a comprehensive study of pollen records, organic geochemical proxies, lake-level records, sediment accumulation rate(SAR) and organic C accumulation rate(CAR) in China since the Holocene. We also include numerical climate classification and lake-level simulations, to investigate variations of lake C sequestration, hydrological status and vegetation during the Holocene. Results indicate that the evolution of lake C accumulation showed an out-of-phase relationship with hydrological status and vegetation in China. Lake C accumulation exhibited an overall trend of increasing from the early to late Holocene in response to gradually increasing terrestrial organic matter input. However, China as a whole experienced the densest vegetation cover in the middle Holocene, corresponding to the mid-Holocene optimum of a milder and wetter climate. Optimal hydrological conditions were asynchronous in China; for example, early Holocene in Asian monsoon dominated areas, and middle Holocene in westerlies controlled regions. Our synthesis indicated that climate change was the main factor controlling the long-term variability in lake C accumulation, hydrologic conditions, as well as vegetation, and human influences were usually superimposed on the natural trends.     

Quantification of Holocene lake-level changes in Finnish Lapland using a cladocera – lake depth transfer model

During recent years, numerous studies dealing with Holocene lake level fluctuations have been conducted in Finnish Lapland. However, no quantification of lake level variations exists to date. Here, we applied a recently developed modern cladocera – lake depth transfer model to subfossil cladocerans analysed from three small and shallow (< 6 m) kettle-hole lakes in northwestern Finnish Lapland to provide estimates of the amplitudes of long-term lake-level changes in the region. The quantitative inferences were compared to pollen, charcoal and geochemical records from one of the study sites. The lake levels were inferred to be high during the early Holocene; they faced marked reduction up to 4–6 m in the mid-Holocene (≈7000–4000 cal yr BP), and rose again during the latter part of the Holocene. There is some indication of lowered lake levels around 1500 cal yr BP, but interpretation of such small-scale changes is hazardous due to large prediction errors in the initial cladoceran model. The overall pattern of the Holocene lake level variation generally followed the regional changes in climate humidity as reconstructed in previous studies by means of other sedimentary proxy indicators, such as pollen and oxygen isotopic compositions. We postulate that changes in winter precipitation may have had a greater influence on lake-levels than variations in summer precipitation or evaporation.     

Mid- to- late Holocene hydroclimatic changes on the Chinese Loess Plateau: evidence from <Emphasis Type="Italic">n</Emphasis>-alkanes from the sediments of Tianchi Lake

We have reconstructed the history of mid-late Holocene paleohydrological changes in the Chinese Loess Plateau using n-alkane data from a sediment core in Tianchi Lake. We used P_aq (the proportion of aquatic macrophytes to the total plant community) to reflect changes in lake water level, with a higher abundance of submerged macrophytes indicating a lower water level and vice versa. The P_aq-based hydrological reconstruction agrees with various other lines of evidence, including ACL (average chain length), CPI (carbon preference index), C/N ratio and the n-alkane molecular distribution of the sediments in Tianchi Lake. The results reveal that the lake water level was relatively high during 5.7–3.2 ka BP, and decreased gradually thereafter. Our paleohydrological reconstruction is consistent with existing paleoclimate reconstructions from the Loess Plateau, which suggest a humid mid-Holocene, but is asynchronous with paleoclimatic records from central China which indicate an arid mid-Holocene. Overall, our results confirm that the intensity of the rainfall delivered by the EASM (East Asian summer monsoon) is an important factor in affecting paleohydrological changes in the region and can be considered as further evidence for the development of a spatially asynchronous “northern China drought and southern China flood” precipitation pattern during the Holocene.     

Holocene millennial-scale climate variations documented by multiple lake-level proxies in sediment cores from Hurleg Lake,Northwest China

Millennial-scale climate variability has not been well documented in arid northwest China due to the scarcity of high-resolution, well-dated paleoclimate records. Here we present multi-proxy records from sediment cores taken in freshwater Hurleg Lake on the northeastern Tibetan Plateau, which reveal millennial-scale lake-level and climate variations over the past 8,000 years. This high-elevation region is very sensitive to large-scale climate change, thus allowing us to better understand Holocene climate variations in East Asia. The lake-level record, derived from lithology, magnetic mineralogy, carbonate isotopes, ostracode shell isotopes and trace elements, X-ray fluorescence (XRF), and gray scale data, indicates a highly variable and generally dry climate from 7.8 to 1 ka (1 ka = 1,000 cal year BP), and a relatively stable and wet climate after 1 ka. Superimposed on this general trend, six dry intervals at 7.6–7.2 ka, 6.2–5.9 ka, 5.3–4.9 ka, 4.4–3.8 ka, 2.7–2.4 ka, and 1.7–1.1 ka were detected from the high-resolution carbonate content and XRF data. The generally dry climate between 7.8 and 1 ka was almost synchronous with the decrease of East Asian and Indian monsoon intensities shortly after 8 ka. The six dry intervals can be correlated with weak monsoon events recorded in the East Asia and Indian monsoon regions, as well as the North Atlantic cold events. Our data suggest that millennial-scale monsoon variations could cause highly variable climate conditions in arid northwest China during the Holocene. These millennial-scale climate variations may reflect changes in solar variation and/or changes in oceanic and atmospheric circulation.