排序方式: 共有29条查询结果,搜索用时 31 毫秒
1.
A synthesis of Holocene pollen records from the Tibetan Plateau shows the history of vegetation and climatic changes during the Holocene. Palynological evidences from 24 cores/sections have been compiled and show that the vegetation shifted from subalpine/alpine conifer forest to subalpine/alpine evergreen sclerophyllous forest in the southeastern part of the plateau; from alpine steppe to alpine desert in the central, western and northern part; and from alpine meadow to alpine steppe in the eastern and southern plateau regions during the Holocene. These records show that increases in precipitation began about 9 ka from the southeast, and a wide ranging level of increased humidity developed over the entire of the plateau around 8-7 ka, followed by aridity from 6 ka and a continuous drying over the plateau after 4-3 ka. The changes in Holocene climates of the plateau can be interpreted qualitatively as a response to orbital forcing and its secondary effects on the Indian Monsoon which expanded northwards 相似文献
2.
青藏高原全新世植被的时空分布 总被引:11,自引:2,他引:11
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 相似文献
3.
4.
对柴达木盆地察尔汗古贝壳堤剖面的沉积物进行孢粉分析,结果显示这个地区植被与气候在晚更新世中晚期经历以下几个阶段的变化:36.2~31.2kaB.P.(未校正14C年代,下同)期间,以禾本科、藜科、蒿属、莎草科为主,发育草原-草甸植被,气候温和湿润,盘星藻出现较多,反映淡水湖泊,水深在10m左右;31.2~27.6kaB.P.期间,松属、云杉属、桦属等为主的木本植物的含量增加,周围山地森林发育,表明气候温暖,降水量增多。但由于蒸发量大,有效湿度下降,荒漠成分柽柳属等增加,盘星藻在30kaB.P.以后消失,反映湖泊盐度增大;27.6~23.3kaB.P.期间,植被中荒漠成分显著增加,周围山地森林萎缩,气候趋向相对寒冷干旱,湖面积缩小;23.3~18.0kaB.P.,孢粉浓度很低,蒺藜科、藜科等荒漠成分明显增加,植被稀疏,已趋向荒漠化草原,反映气候寒冷干旱。从整个剖面来看,主要的陆生植物孢粉类型为禾本科、柽柳属、蒺藜科、麻黄属、松属、云杉属、柏科、胡桃属和桦属等,藜科和蒿属含量很少,这与柴达木盆地东部地区的表土分析结果完全不同,也与其他草原以及荒漠草原的表土花粉结果相异。这说明晚更新世中晚期柴达木盆地东部地区的植被和现在无法进行比较,气候环境与现在显著不同。 相似文献
5.
神农架大九湖15.753kaB.P.以来的孢粉记录和环境演变* 总被引:10,自引:2,他引:10
根据对大九湖297cm厚的泥炭地层10个AMS 14 C年龄的测定以及148块孢粉样品的分析,发现每块样品的孢粉(浓度)含量都很高,植物种类繁多,分属于137(科)属,可划分为6个孢粉组合带,植被类型演替大体为:含少量常绿树种的针阔叶混交林—含常绿阔叶树种的落叶阔叶林—常绿落叶阔叶林—含常绿阔叶树种的落叶阔叶林—含少量常绿树种的针阔叶混交林。孢粉带Ⅰ(15.753~11.280kaB.P.)记录了该区域晚冰期及其向全新世过渡时期冷暖波动频繁的气候条件,其中亚带Ⅰ -1(15.753~15.549kaB.P.),Ⅰ -3(14.936~14.505kaB.P.)和Ⅰ -5(12.655~11.280kaB.P.)可能分别对应最老仙女木期、老仙女木和新仙女木冷期,而亚带Ⅰ -2(15.549~14.936kaB.P.)和Ⅰ -4(14.505~12.655kaB.P.)分别对应博令和阿勒罗德暖期。孢粉带Ⅱ(11.280~9.218kaB.P.)代表了由晚冰期冷湿气候向全新世温暖气候转换的早全新世缓慢升温的过渡时期。孢粉带Ⅲ(9.218~7.530kaB.P.)代表中全新世前期的气温波动上升期,7.7kaB.P.前后达到最高温。孢粉带Ⅳ(7.530~4.051kaB.P.)代表中全新世适宜期,水热配置条件最佳。孢粉带Ⅴ(4.051~0.911kaB.P.)体现晚全新世温干的气候。孢粉带Ⅵ(0.911~0kaB.P)反映了大九湖温凉稍湿的气候。 相似文献
6.
野外调查表明,沼泽-湿地相地层在黄土高原西部广泛分布,测年结果表明该地层形成于9~3.8 kaBP.该地层有机质含量很高,指示区域普遍湿润;粒度记录表明9~3.8 kaBP 冬季风较弱.孢粉记录表明,9~3.8 kaBP 黄土高原西部植被繁茂,孢粉组成中乔灌木成分的含量最高可达80%以上.水生-湿生类型的蜗牛在9~3.8 kaBP大量出现, 其总体积约占该时段地层体积的25%,也指示区域普遍湿润;3.8 kaBP以后气候总体趋向干旱.可能的机制是(1)65°N 的太阳辐射在9~8 kaBP达到峰值,巨大的海陆热力差异使季风迅速强盛;(2)在6 kaBP前后北半球夏季辐射增强,加强了东亚季风的水汽输送;(3)全新世中期良好的植被的正反馈加强了夏季风;(4)长尺度的厄尔尼诺活动在全新世中期较弱,对东亚季风有加强作用. 相似文献
7.
在新生代全球变冷的背景下,亚洲环境变化的主要特征之一是季风气候的形成和演化。渭河盆地具有连续的新生代沉积序列,为研究新生代植被演化历史,探究季风的阶段性变化特征提供了良好材料。文章通过分析和综合集成渭河盆地新生代的孢粉记录,初步重建了新生代以来的古植被和古气候变化序列。始新世植被以含热带亚热带乔木成分的落叶阔叶林为主,气候暖湿;渐新世植被类型为含常绿树种的落叶阔叶林,气候相对暖热湿润;早中新世植被以落叶阔叶树为主,气候温暖湿润,晚中新世植被以森林草原为主,气温和降水比早中新世略有降低;上新世植被为落叶阔叶林和针叶林交替出现,后期变为森林草原,气候向干凉方向发展;第四纪以来,植被向森林草原—稀疏的森林草原—草原发展,气候变化趋于凉干。新生代以来降水阶段性减少,与全球变冷趋势基本一致,可能揭示了全球变冷对构造时间尺度亚洲季风降水和植被演替的影响。
相似文献8.
长江中下游地区7500—5000aB.P.气候变化序列的初步研究 总被引:5,自引:0,他引:5
孢粉分析方法可以比较客观地反映古植被类型,而各植被类型只能在一定的气候指标范围内生长。本文根据这一基本原理,利用现代植被生长的基本气候指标和有关气象资料,对长江中下游地区7500—5000aB.P.的孢粉资料进行处理、转化,从而得出这一阶段每500年一个时间段的气候变化序列。研究结果表明,研究区在7500—5000aB.P.时间内,年平均温度偏暖于今日-0.1—1.5℃,最高温出现在6500—6000aB.P.,气温高于现在1.5℃。 相似文献
9.
10.
The catchment of South Luohe River in Central China is an important region for investigating modern pollen-environment relationship, because it is located in the transitional zone between south and north China, an environment which is sensitive to climate changes. In this study, 40 surface samples under ten vegetation types were collected to reveal the relationship between pollen assemblages and vegetation. The results show that the surface pollen assemblages reflect the vegetation quite well. In forest topsoils, the average of arboreal pollen content is greater than 40%, and the Selaginella sinensis spore is high. As to sparse forest grassland and shrub community, the average arboreal pollen is 13.2% and 16.6% respectively, and the shrub pollen is relatively higher than that of grassland samples. The grassland and farmland are characterized by low percentage of tree and shrub pollen(<10% and <1%), and high percentage of herbs(>80%). Pinus, Quercus and some other arboreal pollen can indicate the regional vegetation because of their dispersal ability. Quercus pollen is under-representative and so is Pinus. Artemisia pollen is significantly over-represented, has poor correlation with the plant coverage, and may reflect human disturbance. Gramineae can indicate plant quite well, but with low representation. High content of Chenopodiaceae probably suggests human impact. Predominant Selaginella sinensis can be used as an indicator of forest environment. Cluster analysis and principal components analysis of pollen assemblages can distinguish forest and non-forest vegetation well. The former method is better at separating pine and mixed forests, while the latter is more stable and could better differentiate farmland and other non-forest area. The first axis of PCA mainly reflects the humidity. 相似文献