西藏纳木错和藏北高原古大湖晚更新世以来的湖泊演化与气候变迁

根据野外水准测量与室内实验分析，本文探讨了西藏纳木错和藏北高原古大湖晚更新世以来的湖泊演化和气候变迁。在纳木错沿岸拔湖48m以下，发育了6级湖岸阶地，拔湖48-139．2m发育有高位湖相沉积。研究表明，纳木错湖泊发育与藏北高原东南部古大湖演化可划分为3个阶段：①116-37ka B．P．间的古大湖期；②37-30ka B．P．间的外流湖期；③30kaB．P．以来的纳木错期。在古大湖阶段，包括纳木错、色林错和扎日南木错、当惹雍错等藏北高原东南部的一大批现代大、中、小型湖泊，都是互相连通的一个古大湖，其范围可能超过了现代的藏北内、外流(怒江)水系的分水岭。它或许还与藏北高原南部和西部的其他古湖相连，成为统一的藏北高原“古大湖”。通过对纳木错湖相沉积形成时代与深海氧同位素对比，易溶盐、pH值、地球化学、介形类和孢粉分析等的综合研究发现，湖相沉积记录了自晚更新世以来的湖泊演化和气候变迁信息。资料显示古大湖期湖面最高，气候温和清爽；外流湖期湖面急剧下降，气温和湿度较现今略高；纳木错期以来气候经历了全新世最宜期的暖湿后日益干旱化，气温波动，湖面持续下降。表明自晚更新世以来该区气候在逐渐变干的总趋势的基础上，经历了多次明显的冷暖与干湿波动。     

西藏纳木错与仁错—久如错连通和藏北高原古大湖的发现

西藏是中国海拔最高、湖泊最多的省区，藏北内流区则集中了西藏最多的湖泊和大湖。其中位于藏北内流区东南部、藏语意为天湖的纳木错，则是西藏面积（１９４０ｋｍ２）最大和海拔（４７１８ｍ）最高的大湖。前人仅少量报道过该湖的湖岸阶地与古湖岸线，并推论该湖在青藏高原的“大湖期”（４０～２８或４０～２５ｋａＢ．Ｐ．）时，有可能是以河道通过仁错（海拔４６４８ｍ）而与色林错等湖泊相连通的外流湖。２０００—２００１年夏，作者在纳木错沿岸的地质调查与１∶２５万地质填图（图１）中发现：在作曲卡河下游、玛尔扃北岸、塔吉古日…     

西藏纳木错与仁错-久如错连通的地质记录

西藏是我国湖泊最多的省区。藏北内流区则集中了西藏最多的湖泊和大湖。其中,位于藏北内流区东南部的纳木错,则是西藏面积最大(1920ｋｍ₂)和海拔最高(4718ｍ)的大湖。前人仅少量报道过该湖的湖岸阶地与古湖岸线,并推论该湖在青藏高原的“大湖期”(40000～28000ａＢ.Ｐ.或40000～25000ａＢ.Ｐ.)时,有可能是以河道通过仁错(海拔4648ｍ)而与色林错相通的外流湖。2000年夏,作者在纳木错沿岸的考察中发现:在作曲卡下游、夺玛半岛东南岬角、玛尔北岸、塔吉古日西北坡、昂崩与昂千南麓等地的湖滨平原上,分布着     

季风与西风对青藏高原全新世气候变化的影响:同位素证据

青藏高原气候变化在冰期-间冰期、千年、十年际和季节尺度上受亚洲季风和西风环流的交互影响,表现出显著的区域性特征。然而全新世以来青藏高原气候变化的机制还不甚清楚,主要原因之一是缺少指示意义明确的古气候代用指标。课题组近年来利用叶蜡氢同位素(δDwax)重建了高原东北部的青海湖、中北部的令戈错、中部的达则错、西部的班公错和阿翁错不同时间尺度的大气降水同位素记录,本文对上述工作进行总结,并结合青藏高原全新世以来已发表的其他地点的同位素和古水文记录,揭示全新世以来季风与西风对青藏高原不同区域气候变化的影响。结果表明:1)早全新世青海湖、令戈错、班公错和阿翁错4个湖泊均主要受夏季风影响,夏季风可以影响到青藏高原的大部分地区,此时夏季风在青藏高原的最北界限可能位于青海湖以北、克鲁克湖以南。2)中全新世青海湖、班公错和阿翁错受夏季风影响逐渐减弱;然而令戈错在7.0~4.5 ka水汽主要来源于西风环流。3)晚全新世青海湖和班公错受季风的影响进一步减弱;西风在3.5~1.7 ka和2.0~1.0 ka分别影响到高原中部的令戈错和达则错;晚全新世阿翁错受冰川融水补给影响降水同位素异常偏负。4)本研究表明在中晚全新世季风较弱的时期,西风能够深入到青藏高原内部地区,给高原内部地区带来冷湿的水汽。     

全新世青藏高原及周边典型湖泊演化模拟

湖泊在区域水循环和生态系统演化中起着重要作用。在以往的湖泊演化研究中多利用湖泊沉积物代用指标重建湖泊与气候变化过程,缺乏对湖泊水循环特征的定量研究。基于瞬态气候演变模型、特征时段流域和湖泊水量,以及能量平衡模型,对青藏高原及周边6个典型湖泊进行了水量平衡计算和湖泊演化模拟。结果表明：小柴达木湖和罗布泊全新世期间降水和蒸发的变率较小;色林错和纳木错早中全新世降水和蒸发的变率较大,主要受控于温度和净辐射变化;青海湖和猪野泽早中和中晚全新世降水和蒸发变率接近。系统分析了全新世期间青藏高原不同气候区湖泊水循环要素演化过程,有助于理解该区湖泊演化的古气候学机理。     

1979—2021年鄂陵湖和扎陵湖结冰日变化及主控因素分析

湖冰物候过程影响着湖泊冰封期湖泊环境的初始、发展和结束条件以及湖-气作用等。为了探究青藏高原淡水湖泊湖冰物候变化趋势及影响因素,对FLake模型进行改进,并使用MODIS温度数据进行验证,以鄂陵湖和扎陵湖为例,重建其1979—2021年结冰日数据序列,利用模型对湖泊结冰日进行敏感性分析。结果表明：改进的FLake-SELF模型对两湖的结冰日计算精度提升了35%,重建序列显示鄂陵湖和扎陵湖结冰日分别以4.5 d/(10 a)、3.8 d/(10 a)的速率推迟;气温变暖、风速降低和水汽压增加是导致两湖结冰日推迟的最主要气象因素,气温、水汽压和风速的年际差异是造成两湖结冰日年际波动的关键气象因素;相同的气候变化条件下,湖泊深度的不同是造成两湖结冰日及其变化速率差异的原因;较深的湖泊,结冰日年际波动性越大、变化速率越大,对气候变化响应更为敏感。     

西北地区近年来内陆湖泊变化反映的气候问题

内陆湖泊是气候变化敏感的指示器,高山湖泊处于自然状态,受人类活动影响较小,能够较真实地反映气候状况,而内陆河尾闾湖变化是自然和人类活动共同作用的结果.利用NOAA/AVHRR、EOS/MODIS卫星资料和相关文献资料研究分析了祁连山哈拉湖和大、小苏干湖,黑河下游东居延海、新疆博斯腾湖、塞里木湖和艾比湖面积变化.结果表明,近年来祁连山哈拉湖面积呈逐渐扩大趋势,大、小苏干湖面积变化稳定;2002年是黑河流域降水较多的年份;2002年新疆内陆和高山湖泊面积显著增加,预示着这些地区降水增多,冰雪融化加快.内陆湖泊变化应引起人们的关注.     

青藏高原东北部新近纪古流向与物源分布对隆升的响应

通过对青藏高原东北部11个新近纪沉积盆地的沉积相演化、古流向和物源演变的详细对比研究,揭示了研究区新近纪4次沉积演变与构造隆升的响应.①中新世早期(23～19.5Ma):阿牙克库木湖、柴达木、德令哈和酒泉盆地的古流向和物源分析表明东昆仑和阿尔金已经抬升成剥蚀区.循化、贵德和临夏等盆地物源和古流向指示西秦岭和拉脊山也已成为隆起区.区域上整体地势差异不显著.②中新世早中期(17.5～15Ma):区域湖盆面积扩大,阿牙克库木湖、索尔库里、柴达木和酒泉盆地的资料反映东昆仑、阿尔金和祁连山已经全面隆升,贵德循化、临夏盆地的古流向反映为盆地周缘型,指示西秦岭和拉脊山明显抬升,区域差异隆升造成盆地凹陷扩张进入湖泛期.③中新世中晚期(10～7Ma):阿牙克库木湖、索尔库里、柴达木和酒泉盆地沉积物的粒径和沉积速率增大,与热年代学证据一致,揭示出阿尔金山和祁连山进一步快速隆升.贵德、循化和临夏盆地古流向和物源反映为显著的多源性,除西秦岭和拉脊山外,位于循化和临夏两盆地间的积石山也开始隆起.④上新世(5.3Ma以来):索尔库里、柴达木和酒泉盆地古流向没有明显变化,沉积速率和粒径继续增大,阿尔金和祁连山加速隆升为高海拔地貌.贵德盆地主物源区是拉脊山.区域上,地势差异加强,湖盆被肢解后逐步萎缩消亡.     

西藏纳木错晚更新世以来湖面变化和湖相沉积中粘土矿物显示的环境信息

通过对西藏海拔最高、面积最大湖泊-纳木错周缘湖相沉积、湖岸堤的野外调查和湖岸阶地的水准测量,发现在纳木错沿岸拔湖48m以下,发育有6级湖岸阶地,拔湖48~139.2m发育有高位湖相沉积。湖相沉积物的同位素测年结果表明,纳木错湖泊发育与藏北高原东南部古大湖演化可划分为3个阶段:①116~37kaB.P.间的古大湖期;②37~30kaB.P.间的外流湖期;③30kaB.P.以来的纳木错期。根据纳木错晚更新世以来湖相沉积中粘土矿物的X光衍射分析结果,以及采用比值法、高岭石法和衍射峰法的研究,探讨了粘土矿物所显示的环境变化信息。粘土矿物成分变化表明,该区已具备了寒温带干旱、半干旱区的气候环境特征。为研究青藏高原的湖泊演化、气候变化、古地理变迁及其隆升过程等提供了新资料。      

青海扎陵湖和鄂陵湖盆地第四纪河湖相地层研究

通过对扎陵湖和鄂陵湖沿岸的湖积阶地中湖相沉积的野外地质调查和实测剖面,对分布于盆地内的第四纪早更新世-全新世湖相地层进行了详细的研究和划分、重新厘定了该区第四纪岩石地层单元,确立了生物地层和年代地层序列.建立了青海东南部地区第四纪早更新世-全新世湖相地层单位-黄河源群(QH),黄河源群是由第四系下更新统野生沟组(Qp~1γ)、中更新统鄂陵湖组(Qp~2e)、上更新统大野马岭组(Qp~3d)和全新统黑河乡组(Qhh)等4个组组成.为青藏高原湖泊演化、气候变化、古地理变迁研究,以及第四纪地层的划分与对比等提供了新资料.     

Characteristics of the change of major lakes on the Qinghai Tibet Plateau in the last 25 years

On the Qinghai-Tibet Plateau there are three super large lakes, the Qinghai Lake, Nam Co and Siling Co, and eleven large lakes, the Zhari Nam Co, Tangra Yumco, Ayakkum Lake, Banggong Co, Har Lake, Ngoring Lake, Yamzho Yumco, Gyaring Lake, Chibuzhang Co, Ulan Ul Lake and the Ngangla Ringco. The authors studied the changes of these major lakes in the past 25 years, based on interpretations of the MSS images obtained during the middle 1970s and ETM⁺ images obtained in the late 1990s or at the beginning of the 21st century. The study shows that: the areas of the Har Lake andNgoring Lake have remained relatively stable; the areas of the Qinghai Lake, Zhari Nam co, Tangra Yumco, Ayakkum Lake, Gyaring Lake, Ulan Ul Lake and Ngangla Ringco have been reduced to varying degrees, of which the areas of the Qinghai Lake and Ulan Ul Lake have decreased most sharply by 60.60 km² and 59.80 km² respectively; the areas of the Nam Co, Siling Co and Bangong Co have increased more or less, of which the area of the Siling Co has increased most sharply by 140.42 km². The analysis on the changes in areas of major lakes has provided new materials for the study of the lake evolution, climatic change and environmental variation on the Qinghai-Tibet Plateau. __________ Translated from Geological Bulletin of China, 2007, 26(12): 1633–1645 [译自: 地质通报]     

Synchronous pattern of moisture availability on the southern Tibetan Plateau since 17.5 cal. ka BP – the Tangra Yumco lake sediment record

A possible asynchronicity of the spatial and temporal moisture availability on the Tibetan Plateau has been a controversial subject of discussion in recent years. Here we present the first attempt to systematically investigate possible spatial and temporal variations in moisture availability by examining two lakes, Tangra Yumco and Nam Co, on an east–west transect on the southern Tibetan Plateau using identical proxies for palaeoenvironmental reconstruction. In this study, an independent record from Tangra Yumco was analysed applying a multi‐proxy approach to reconstruct variations in moisture availability since the Lateglacial. Results were subsequently compared with previously published records from Nam Co and additional records from Tso Moriri (northwestern Himalaya) and Naleng Co (southeastern Tibetan Plateau). Our results show that Tangra Yumco was at least partially ice covered prior to 17.1 cal. ka BP. A temperature rise after 17.1 cal. ka BP probably resulted in thawing of the permafrost. At 16.0 cal. ka BP moisture availability increased, representing an initial monsoonal intensification. Warmer conditions between 13.0 and 12.4 cal. ka BP and cooler conditions between 12.4 cal. ka BP and the onset of the Holocene reflect the Bølling‐Allerød and Younger Dryas. At the onset of the Holocene moisture availability rapidly increased, with moisture highest prior to 8.5 cal. ka BP when temperatures were also highest. After 8.5 cal. ka BP the moisture availability gradually decreased and showed only minor amplitude variations. These findings are consistent with the records from large lakes like Nam Co, Tso Moriri, and Naleng Co, revealing a synchronous pattern of moisture availability on the southern Tibetan Plateau.     

Evolution of an Ancient Large Lake in the Southeast of the Northern Tibetan Plateau

Nam Co is the largest (1920 km2 in area) and highest (4718 m above sea level) lake in Tibet. According to the discovery of lake terraces and highstand lacustrine deposits at several places in Nam Co and its adjacent areas, the authors confirm the existence of an ancient large lake in the southeastern part of the northern Tibetan Plateau. On the basis of the U-series, 14C and ESR dating, coupled with the levelling survey of lake deposits and geomorphology, the evolutionary process of the ancient large lake in the southeastern part of the northern Tibetan Plateau may fall into three stages: (1) the ancient large lake stage at 115-40 ka BP, when the ancient lake level was 140-26 m above the level of present Nam Co; (2) the outflow lake stage at 40-30 ka BP, when the ancient level was 26-19 m above the present lake level; and (3) the Nam Co stage since 30 ka BP, when the ancient lake level was < 19 m above the present lake level. During the ancient large lake stage, a large number of modern large, medium-siz     

黄河源区水环境变化及黄河出现冬季断流的原因

自1954年有水文观测资料以来，黄河曾在青海省玛多县黄河沿水文站发生过3次断流。本文在分析黄河源区水环境特征及其影响因素的基础上指出，鄂陵湖、扎陵湖的环湖融区调节能力低，当遇到连续干旱、冬季其调节水量不足以维系黄河径流时便会发生断流，这是断流的主因。湖水位降低、开采沙金、过度放牧等自然和人为因素也会对黄河发生断流产生影响。鄂陵湖口附近黄河上修建的水电站开始蓄水，提高了两湖及环湖融区的调节能力，今后黄河冬季出现断流的可能性将大为降低。     

Holocene Saline Sedimentary Record in Tibetan Dong Co (Lake) and Its Significance on Palaeoclimate

HOLOCENE SALINE SEDIMENTARY RECORD IN TIBETAN DONG CO(LAKE) AND ITS SIGNIFICANCE ON PALAEOCLIMATE     

西藏西部昂拉仁错地区下白垩统岩石地层特征及空间变化规律

将西藏昂拉仁错地区下白垩统划分为则弄群、多尼组、郎山组和捷嘎组4个正式岩石地层单位。讨论了各组段的空间分布、岩石组合特征、沉积环境及横向变化规律。认为多尼组仅分布于班戈-八宿地层分区的东部,在改则厚齿玛里以西相变尖灭,与则弄群二段既有上下层位关系又呈横向相变关系。郎山组为只见于昂拉仁错北部班戈-八宿地层分区内的一套稳定碳酸盐台地相沉积,而捷嘎组为只见于昂拉仁错中南部措勤-申扎地层分区内的较活动的火山活动碳酸盐台地相沉积。郎山组与捷嘎组为同时异相关系。     

Microplastic contamination in lacustrine sediments in the Qinghai-Tibet Plateau: Current status and transfer mechanisms

This paper aims to investigate the present situation and transfer mechanisms of microplastics in lacustrine sediments in the Qinghai-Tibet Plateau. The study surveyed the average abundance of microplastics in sediments. The abundance of microplastics in sediments of lakes from the Qinghai-Tibet Plateau is 17.22–2643.65 items/kg DW and 0–60.63 items/kg DW based on the data of the Qinghai Lake and the Siying Co Basin. The microplastic abundance in sediments from small and medium lakes is very high compared to that in other areas in the world. Like microplastics in other lakes of the world, those in the lakes in the Qinghai-Tibet Plateau mainly include organic polymers PA, PET, PE, and PP and are primarily in the shape of fibers and fragments. The microplastic pollution of lacustrine sediments in the Qinghai-Tibet Plateau is affected by natural changes and by human activities, and the concentration of microplastics in lacustrine ecosystems gradually increases through food chains. Furthermore, the paper suggests the relevant administrative departments of the Qinghai-Tibet Plateau strengthen waste management while developing tourism and pay much attention to the impacts of microplastics in water environments. This study provides a reference for preventing and controlling microplastic contamination in the Qinghai-Tibet Plateau.©2022 China Geology Editorial Office.     

藏南羊卓雍错流域主要湖泊水质状况及其评价

湖泊水质是研究湖泊变化及其对气候变化响应的重要指标.分析了藏南羊卓雍错流域主要湖泊的水化学指标概况、 水化学组成、 矿化度时空分布及其驱动, 并在此基础上对各湖泊的水质现状进行了评价. 研究表明: 流域内各湖泊水化学性质虽有一定的相似性, 但矿化度等水化学指标浓度存在显著差异, 各湖泊水化学组成亦差异显著. 羊卓雍错和巴纠错均为硫酸盐类-镁组, 沉错为硫酸盐类-钠组, 普莫雍错和空姆错则分别为重碳酸盐类-镁组和重碳酸盐类-钙组. 各湖泊矿化度差异较大的主要原因在于其补给来源不同, 以降水补给为主的湖泊矿化度远高于以冰雪融水补给为主的湖泊. 与全球气候变暖相对应, 各湖泊矿化度变化反映了气候变化的影响, 而水电站运行对羊卓雍错水体化学性质变化有所贡献. 目前, 羊卓雍错、 普莫雍错水质为劣V类, 空姆错、 沉错、 巴纠错水质为V类. 深入探讨该流域水质对气候变化的响应, 亟需更长时间序列的数据支持. 为此, 必须继续在该流域长期开展全方位的水化学观测与水质监测、 评价工作.     

新疆玛纳斯湖沉积物氧同位素记录的古气候信息探讨──与青海湖和色林错比较

内陆封闭湖泊自生碳酸盐氧同位素组成与大气降水同位素组成、空气相对湿度和地面气温这三个参数相关。我国季风带的青海湖与色林错的δ¹⁸O曲线非常相似,说明古气候变化受相同因素驱动。在10500～9500aB．P．的末次冰期向全新世的过渡期,这两个湖泊的δ¹⁸O值大幅度下降,这是夏季风雨水的低δ¹⁸O值的缘故。属于西风带的玛纳斯湖和季风带的青海湖的δ¹⁸O曲线基本上是对称的。大约9500～4000aB．P,图形由对称转变为相似,据此推论当时夏季风的影响范围可能达到新疆北部。