关于季风交界带与古冻土及泥石流成因机制分析

季风交界带水热状况变化明显 ,其空间分布与古冻土 (晚更新世冰缘环境 )和泥石流分布 3者基本吻合 ,表明 3者在成因上有一定的内在联系 。

青藏高原中、东部全新世以来多年冻土演化及寒区环境变化

古冻土存在的依据和判别标志主要是古冻土遗迹（深埋藏多年冻土层、古冻土上限、融化夹层、厚层地下冰）和古冰缘现象（古冻胀丘、古融冻褶皱、砂楔、土楔、冰楔假型、风成沙丘、黄土层、厚层泥炭和腐殖质层等）。文章结合大量的测年数据，利用古代和现代冻土以及冰缘现象的时空分布差异综合分析对比，将全新世以来青藏高原多年冻土演化过程和环境变化划分为6个较明显的时段：早全新世的气候剧变期（10800aB．P．至8500-7000aB．P．）、中全新世大暖期（8500-7000aB．P．至4000-3000aB．P．）、晚全新世寒冷期（4000-3000aB．P．至1000aB．P．）、晚全新世温暖期（1000aB．P．至500aB．P．）、全新世末小冰期（500aB．P．至100aB．P．）及近代升温期（100aB．P．至今）；同时，概述了各时段高原冻土的发育条件、分布范围及总面积，和当时高原上的古气候、古地理环境。

柴达木盆地中的砂楔及其意义

冰楔假形和原生砂楔是指示古冻土发育的重要证据。两者虽然具有相似的外观形态，但形成过程不同，在反映古气候、古环境和古冻土演化等方面具有不同的指示意义。在利用地层中的楔形构造推测古环境时，确定其类型是正确解读其环境意义的前提。本文讨论了柴达木盆地发现的楔形构造，通过楔形围岩和充填物中的一些微结构判断其属于原生砂楔，进而探讨了这些砂楔代表的环境意义和多年冻土发育状况。柴达木盆地中的砂楔主要形成在末次冰消期的Heinrich1（H1）和YoungerDrays两次降温事件期间。这表明，末次冰消期，柴达木盆地地表几乎全部被风沙覆盖，处于极端干旱的沙漠环境，年平均气温较现在降低6℃左右，多年冻土下界较现在下降了约1000m。然而，多年冻土并没有占据整个盆地，在盆地中部和南部保留着大片融区，据此推测，即使末次冰期时期，柴达木盆地仍然保留一定面积的融区。末次冰期以来，青藏高原主体和祁连山两大现代多年冻土区并没有通过柴达木盆地连成一片。

Vegetation Changes from 2014 to 2023 in the Mongolian Plateau Permafrost Region under Climate Change

The permafrost region is one of the most sensitive areas to climate change.With global warming,the Mongolian Plateau permafrost is rapidly degrading,and its vegetation ecosystem is seriously threatened.To address this challenge,it is essential to understand the impact of climate change on vegetation at different permafrost degradation stages on the Mongolian Plateau.Based on the general permafrost distribution,in this study,we divided different permafrost regions and explored the response of vegetation to climate change at different stages of permafrost degradation by the idea of“space instead of time”from 2014 to 2023.The results of the study showed that:(1)Normalized difference vegetation index(NDVI)values showed a decreasing trend,and the proportion of the decreasing region was in the order of sporadic permafrost region>isolated and sparse permafrost region>continuous and discontinuous permafrost regions.(2)The main controlling factors of vegetation growth in permafrost regions are different,air temperature is the main controlling factor of vegetation growth in isolated and sparse permafrost region(r=-0.736)and sporadic permafrost regions(r=-0.522),and precipitation is the main controlling factor of vegetation growth in continuous and discontinuous permafrost region(r=-0.498).(3)The response of NDVI to climate change varies at different stages of permafrost degradation.In the early stages of permafrost degradation,increased land surface temperature(LST)and air temperature favored vegetation growth and increased vegetation cover,whereas increased precipitation impeded vegetation growth;as the permafrost degraded,increased LST and air temperature impeded vegetation growth,whereas increased precipitation promoted vegetation growth.