40～30 ka BP期间高湖面稳定存在时青藏高原西南部封闭流域的古降水量研究

依据封闭流域全流域水量平衡模式，模拟了青藏高原西南部3个封闭流域在40～30 ka BP期间，高湖面稳定存在时期的古水量平衡，重建了各流域的古降水量。结果表明色林错－纳木错流域、扎布耶－拉果错流域、扎仓茶卡－别苦则错流域当时的降水量分别约为585±25 mm、565±25 mm、475±25 mm，相当于现在降水量的1.7、3.1、4.8倍。     

青藏高原全新世植被的时空分布

根据青藏高原 30个点湖泊的孢粉记录综合研究显示 :在进入全新世之前 (12kaBP以前 )除最东南部外 ,高原从东到西均发育为荒漠草原植被 .全新世早期 (12～ 9.0kaBP)高原东南部 (10 4°～ 98°E)为落叶阔叶林 /针阔叶混交林 ,季风已进入本区 ,气温比前期上升 2～ 4°C ,降水波动于 35 0～ 5 5 0mm之间 .中部 (98°～ 92°E)为草甸或灌丛草甸 ,再向西至 80°E左右为草原植被 ,气候寒冷干燥 ,平均气温比现在低 4.5～ 5 .5℃ .最西部 10 .5～ 9.9kaBP出现相当于欧洲新仙女木气候倒转事件 .全新世中期 (9.0～ 3.2kaBP)高原由东向西古植被依次发育为针阔混交林或硬叶阔叶林 (10 4°～ 98°E)→针阔混交林 (98°～ 80°E)→灌丛草甸→草原 (92°～ 80°E) .中期气候比早晚期温暖湿润 ,东南部 1月份气温高于现在 3℃ ,年降水量比现今多 2 5 0mm以上 .中西部气候温暖湿润 ,出现高湖面期 ,年均温高出现在 5℃以上 ;全新世晚期 (3.2kaBP以后 )由东向西古植被依次为硬叶阔叶林→针阔混交林→草甸→草原→荒漠 ,气温降水呈非线性下降 ,越向西下降幅度越大 .东南部 1月份气温比中期下降 4～ 4.5℃ ,年降水少 35 0mm ,东北部最冷月气温比中期下降 8℃左右 .中西部严重干旱 ,湖面降低 ,湖水变咸     

西藏纳木错及邻区全新世气候与环境变化的地质记录

综合分析了全新世期间内的多种与气候和环境变化密切相关的地质记录,结果表明该区全新世期间的气候变化可划分为3个阶段:1)约11.8～8.4kaBP期间,处于微温期和升温期,气候相对温和稍湿.2)8.4～4.0kaBP期间,为全新世气候最适宜时期或大暖期.该期间的平均气温可能比现今高约5℃,降水量比今多100～200mm.3)4.0kaBP以来,气候整体较为干冷.纳木错湖面发生持续下降,其最大下降幅度可达11.4m.冰川进退和湖面波动表明,该期间内的气候波动过程分别与新冰期和小冰期相对应,其中又各包含了3次明显的冷期,其中新冰期期间的最低年平均气温可达-6℃左右.约1970年以来,区域气候向暖湿方向转化,造成念青唐古拉山西布冰川后退约120～200m,纳木错湖面上涨了约2m.     

青海湖全新世稳定暖湿期的古水量平衡估算

各种地貌学、沉积学等证据揭示了青海湖流域在全新世大暖期是一个温暖湿润的环境,特别是距今6000～7200a.B.P.的稳定暖湿期,湖水位远高于现代.利用内陆湖泊的水热平衡原理,构造了青海湖古水量平衡计算模型.计算结果表明,在全新世稳定暖湿期,流域内的降水量、蒸发量及径流量分别比现代高32.0%、14.0%及67.0%.     

暖湿气候对赛里木湖的影响

赛里木湖集水面积1408km²,湖面面积457km²,最大水深86m,总蓄水量210×10⁸m³,是新疆最大的高山湖泊,湖面海拔2073m,四周高山环绕.20世纪80年代以后,赛里木湖及邻近地区,气温逐渐升高,降水增多,气候趋向暖湿.20世纪80年代气温比前20a平均升高0.4～0.6℃,90年代气温比80年代升高0.3～0.4℃,比前20a平均升高0.7～1.0℃,比前30a平均升高0.6～0.8℃.20世纪90年代,切德克水文站降水量比多年平均多5.4%;匹里青水文站降水量比多年平均多7.0%;温泉气象站增加最多,比多年平均增加20.3%.赛里木湖相邻地区降水径流增多,赛里木湖区的降水径流增大,导致湖水位上升.     

黄旗海湖泊沉积记录的早中全新世大湖期环境的差异性

内蒙古黄旗海H6剖面揭示了最近间冰期古湖泊涨缩的一个完整旋回。基于OSL年代、粒度并结合沉积物地球化学等数据,分析了黄旗海在早、中全新世（约（11.4±1.1～6.7±0.7）ka）大湖期指标记录特点与环境意义。研究认为黄旗海全新世大湖期可分为三个阶段:1）（11.4±1.1～9.3±0.9） ka BP,半深水环境、湖水盐度低、流域存在有利于化学风化的湿润气候条件;2）（9.3±0.9～7.7±0.7） ka BP,湖水变浅、湖泊萎缩、湖泊盐度升高,流域可能存在不利于化学风化的干燥气候;3）（7.7±0.7～6.7±0.7） ka BP,大湖期结束,指标记录存在剧烈波动,揭示气候具有宽幅震荡特征。同时,研究初步认为Mn/Li比值可以作为流域化学风化的指标指示。     

江汉平原沔城M1孔的沉积特征与古环境重建

通过对江汉平原沔城M₁孔湖泊沉积物进行沉积特征、粒度、14C年代、孢粉分析,重建了晚冰期以来该地区古环境、古气候演化的过程和序列:晚冰期后期有一扩张期,气候温湿并出现湖泊相沉积;晚冰期末期气候温凉偏干、河流环境;全新世初期(10-8.9kaBP),气候转向温湿;全新世大暖期(8.9-3.5kaBP),总体上气候温暖湿润,其中6.8-4.9kaBP是最宜期,4.9-4.8kaBP和4.4-4.2kaBP为两次降温事件,4.8kaBP积水湖盆开始形成,3.9-3.5kaBP为云梦泽鼎盛期;全新世晚期(3.5-1.7kaBP),气温较大暖期有所下降,其中3.5-2.5kaBP温凉偏湿,2.5-1.7kaBP较为温湿,湖泊较为稳定,1.7kaBP开始,云梦泽萎缩,钻孔所在位置出露水面。      

西藏扎布耶盐湖30.0 ka B P以来水位与古降水量变化

扎布耶湖9级大型沙砾堤记录了约30．0ka B P以来水位退缩历史，与北部拉果错、南部塔若错的垭口沉积记录了3个湖泊最后分离的时间。本文应用数字地面高程模型(DEM)，计算了扎布耶各级沙堤对应湖面期的湖水面积、体积与含盐量；分析了扎布耶与拉果错、塔若错的分-合历程，计算了各时期汇流盆地总面积；参考湖泊、冰川、孢粉、天文学等多学科关于古温度、辐射平衡的结论，得出了较为可信的计算参数。在此基础上，应用根据西藏实际情况得出的辐射平衡和水面蒸发、陆面蒸发计算模型，代入封闭盆地水量平衡方程，得出了较Kutzbach水-能方程更可靠的降雨量-水域面积／流域面积比的非线性方程，计算出泛湖期(9级沙堤，40．0～28．0ka B P)该区降雨量567 mm／a，盛冰阶时降至350mm／a以下，冰期后增至402mm／a，随后逐步下降直至约Ⅰ-1级阶地时(海拔4421m，3．53ka B P)为280mm／a(约为现代的两倍)。通过定量恢复该区30．0ka B P以来降水量变化，为认识西藏高原湖泊演化和古环境、古季风演化提供了定量依据。     

内蒙古黄旗海全新世湖泊沉积物中Rb、Sr分布及其环境意义

内蒙古黄旗海H3剖面中发育黄旗海全新世高湖面时形成的湖相粉砂质沉积。对全样、77～20μm粒级、小于20,μm粒级沉积物的Rb、Sr含量,以及小于20,μm粒级样品中碳酸盐矿物种类及含量的测试结果表明,全新世早、中期形成的湖泊沉积物中,自生富锶文石是Sr在沉积物中含量较高的主要原因。各粒级沉积物中Rb、Sr含量与沉积物粒度组成的关系表明:Sr倾向富集于黏粒(4,μm)中,可能与湖泊自生碳酸盐以泥晶为主有关,而Rb倾向富集于4～28,μm颗粒粒级中,可能与其硅酸盐矿物碎化过程的特点有关;Sr与Rb存在粒度效应,且二者粒度效应明显不同。Rb/Sr与湖泊、流域的诸多过程及沉积物粒度效应有关,在不同湖泊演化阶段,其具体的环境含义不同,这是湖泊沉积与风化壳的不同之处。     

1970-2009年纳木错湖泊面积扩张的遥感卫星观测证据及原因之商榷

基于不同时期的遥感影像、航测地形图和DEM, 运用GIS和RS技术对纳木错1970-2009年间湖泊面积变化进行了分析, 利用周边气象台站资料, 通过对纳木错湖面蒸发及降水、冰川融水、非冰川区径流补给的趋势性分析, 从流域水量平衡角度商榷了纳木错湖面扩张的原因. 结果表明: 近40 a来纳木错湖泊面积不断扩张, 尤其是近10 a来最为剧烈, 2001-2009年间湖面扩张超过50 km². 流域降水变化是纳木错湖泊面积扩张的直接原因, 另外伴随蒸发力下降, 湖面蒸发减少也是湖泊面积扩张的原因之一.     

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     

Holocene Vegetation and Climate Changes in the Huangqihai Lake Region, Inner Mongolia

A consensus on Holocene climate variability at the modern northern fringe of the East Asian summer monsoon (EASM) region remains elusive. Here, we present a pollen-based reconstruction of vegetation history and associated climate variations of a sediment core from Huangqihai Lake, central Inner Mongolia. During 10.7 to 8.8 cal kaBP, typical steppe with small patches of forest dominated the lake area, suggesting a moderately wet climate, followed by ameliorating climatic conditions until 8.0 cal kaBP as deduced by the expansion of forest. Typical steppe recovered the lake area between 8.0 and 7.2 cal kaBP, reflecting a deterioration of climatic conditions; in combination with other proxy records in the study region, we noticed that severe aridity was prevailed in the lake area between 8.0 and 7.6 cal kaBP. During 7.2 to 3.2 cal kaBP, abundant tree pollen indicated dominance of forest-steppe around the lake, marking regionally wet conditions. A notable absence of broadleaved trees after 5.2 cal kaBP reveals a slight drying trend, and climate deterioration from 4.5 to 4.1 cal kaBP might be linked to the 4.2 ka event. After 3.2 cal kaBP, a transition to steppe was associated with dry conditions in the region. Based on our pollen record and prior paleoclimatic reconstructions in the Huangqihai Lake region, there was a generally-accepted, stepwise shift to a wet climate during the early Holocene, an overall humid climate from 7.2 to 3.2 cal kaBP, and then severe drought for the rest of the Holocene. Moreover, regional comparisons among pollen records derived from lakes situated in the temperate steppe region suggested a roughly synchronous pattern of vegetation and climate changes during the Holocene and demonstrated an intensified EASM during the middle Holocene.     

青藏高原中部色林错中晚全新世以来古气候变化特征

色林错位于青藏高原中部印度季风和西风环流的过渡地带，同时受西风环流和印度季风系统控制，是研究二者进退变化特征的理想场所。本文利用色林错SL 1钻孔中介形虫 Limnocythere inopinata 的丰度及其壳体微量元素Mg/Ca和Mn/Ca比值重建了色林错5. 3 ka BP以来的古气候环境变化特征。5. 3~2. 9 ka BP， L. inopinata 丰度较小，壳体的低Mg/Ca比值和高Mn/Ca比值表明此阶段气候偏冷湿；2. 9~1. 8 ka BP， L. inopinata 丰度较前一阶段增加，壳体Mg/Ca比值略有增长但仍为低值表明气温虽然有所回升但仍然较低，Mn/Ca比值较前一阶段明显降低，指示湖泊水位下降；1. 8 ka BP至今， L. inopinata 丰度达到最大，壳体的高Mg/Ca和Mn/Ca比值指示湖泊温度和水位均呈显著的上升趋势。通过与西风区、过渡区以及印度季风区其他湖泊的环境沉积记录对比，本文认为青藏高原中部地区在中全新世晚期主要受西风环流影响，气温较低，西风带来大量水汽使得湖面呈扩张趋势；而到晚全新世西风环流逐渐北撤，色林错受季风影响更大，季风带来的降水和气温升高导致的冰川融水增加与色林错水位上升有密切关系。     

西藏纳木错盆地116ka以来沉积演化与青藏高原隆升

根据湖相或湖滨相沉积的铀系等时线年龄测定结果,116kaB.P.以来,在西藏纳木错沿岸,发育了拔湖48m以下的6级湖岸阶地和拔湖48m以上,最高至139.2m的高位湖相沉积.可划分出3个沉积相组合,其演化可划分为4个阶段:①116~72kaB.P.,为深湖环境,古湖面拔湖高于现今纳木错140~48m;②72~37kaB.P.,为半深湖环境,拔湖为48~26m;③37~30kaB.P.,为浅湖环境,拔湖26~19m;④30kaB.P.以来,湖水逐渐变浅,拔湖<19m.纳木错盆地沉积与青藏高原隆升响应关系,揭示出高原自116kaB.P.以来先后经历了稳定期、持续逐步较快隆升期(116~37kaB.P.)、急剧强烈阶段性隆升期(37~30kaB.P.)和较稳定期(30kaB.P.以来).青藏高原的隆升是一个多阶段、不等速和非均变的复杂过程.      

西藏扎布耶湖区128～1.4ka BP的微体古生物与环境气候变化

本文主要根据西藏扎布耶湖区SZK02孔所揭露的近84m剖面的沉积物特征与其产的介形类6属20种,轮藻类2属3种,结合14C、ESR、U-series地层测年等,初步认为该区128～1.4ka至少存在5个较明显的气候变化时期。①在128～76.7ka(83.63～57.0m)处于我国末次间冰期时段,气候凉湿,湖盆扩展,在90～81ka期间湖面最高,水质最淡。②76.7～58.6ka(57.0～38.13m)为我国末次冰期早冰阶时期,湖盆收缩,水温低,早期76.7～69.7ka(57.0～47.5m)偏冷湿,中期69.7～65.0ka(47.52～42.64m)气候温干,正逢早冰阶时期;晚期65.0～58.6ka(42.64～38.13m)气候干燥度下降。③58.6～29.1ka(38.13～13.75m)处于我国末次冰期间冰阶时段,早期58.6～51.6ka(38.13～33.07m)偏温湿,为3c暖期;中期51.6～42.5ka(33.07～26.13m)气候干冷,为3b冷期,正临末次冰期中冰阶时;晚期42.5～36.0ka(26.13～20.16m)偏凉湿,湿度更大,再次出现高湖面,为3a暖期;末期36.0～29.1ka(20.16～13.75m),趋向温干。④29.1～11.8Cal.ka(13.75～4.83m),气候趋向干冷,处于末次盛冰期(LGM)、末次晚冰阶时期,湖盆萎缩,水温低。早期29.1～16.6Cal.ka(13.75～6.98m)偏温湿;晚期16.6～13.1Cal.ka(6.98～5.76m)寒冷干燥;至末期13.1～11.7Cal.ka(5.76～4.83m),进一步干燥寒冷,全球新仙女木事件在本区发生。⑤11.7～1.4Cal.ka(4.83～0.65m),大致进入全新世气候期,气候波动大,凉湿与干冷交替频繁发生。在11.7～10.7Cal.ka(4.83～4.42m)时较温湿;10.7～9.5Cal.ka(4.42～4.07m)转向干冷;9.5～9.1Cal.ka(4.07～3.7m)更干冷,湖盆进一步萎缩;9.1～6.3Cal.ka(3.7～2.86m)向温干过渡;6.3～3.6Cal.ka(2.86～1.77m)干冷,湖泊已成盐湖;3.6～1.4Cal.ka(1.77～0.65m),气候趋向冷湿。     

Basin-wide Holocene environmental changes in the marginal area of the Asian monsoon,northwest China

In arid regions, because of spatial variability, using single climate records is difficult to reconstruct the past climate change for the drainage basins. Holocene environmental records were collected from the upper, middle and lower regions of the Shiyang River drainage basin in the marginal area of the Asian monsoon (northwest China). The main objective of this paper was to compare the records from the terminal lake and the middle and upper reaches of the basin to study the basin-wide environmental changes. During the early Holocene the vegetation was sparse, and the effective moisture was relatively low in the basin. The Holocene Climatic Optimum started between 7.0 and 8.0 cal ka BP, during which the lake level reached the highest level in the terminal lake; the vegetation density and the effective moisture reached the highest level during the Holocene in the drainage basin. From 4.7 cal ka BP the terminal lake began to shrink, while the vegetation density decreased dramatically. In the middle and upper regions of the drainage, the effective moisture began to decrease since 3.5 cal ka BP, and the arid tendency was earlier in the terminal lake than it was in the middle and upper regions of the drainage basin. During the early Holocene the relatively arid environment was affected by the gradually intensifying East Asian monsoon and the dry westerly winds. The mid-Holocene Optimum benefited from the intensive East Asian monsoon and the humid westerly winds. Then, the East Asian monsoon retreated since the late-Holocene. In the basin the arid tendency may be related to the retracting of the East Asian monsoon. However, the intensifying acidification after 1.5 cal ka BP may be correlated to the increasing dryness of the westerly winds.