The pedocomplex designated as S1 in the western part of the Chinese Loess Plateau, corresponding to MIS 5, has been investigated with the focus on the S1S3 unit (equivalent to Eemian in Europe). The high-resolution data (2-cm interval, ca. 150 years) of the particle size distribution and the frequency-dependent magnetic susceptibility were used to reconstruct variations in the winter and summer monsoon intensities. The data show that the summer monsoon was strongest and the winter monsoon weakest in the late part of the Eemian interglacial. Contrary to previous reports from the central part of the Chinese Loess Plateau, our results show that the East Asian monsoons in the western part of the Plateau were quite stable during the last interglacial. However, our data do exhibit four abrupt events of intensified winter monsoon during the transition from the penultimate glacial to the last interglacial. Also found were the existence of a time lag between the summer and winter monsoons. That is, the intensity of the winter monsoon started to decline prior to the sudden strengthening of the summer monsoon during the transition from MIS 6 to MIS 5e and it gradually returned to a glacial state after the intensity of the summer monsoon rapidly resumed its glacial state from MIS 5e to MIS 5d. The time lag between the two monsoons might have resulted from the different sensitivity of the two indirect driving forces (ice–snow coverage in high latitudes and sea-surface temperature in low latitudes) to global insolation as the ultimate direct forcing factor. Specifically, the winter monsoon had followed the insolation variations very closely, whereas the summer monsoon had delayed to respond to the insolation variations because of the buffering effect of lower latitude oceans.

The monthly sand and dust deposition flux and modern dust storms were monitored in the northern Qaidam Basin of the Qinghai–Tibetan Plateau. The monthly sand and dust flux varied between 0.57 and 18.12 mg cm−2 month−1 from June 2003 to April 2005, and was well correlated with the monthly extreme wind velocity (Vextr) (r2=0.60, n=23). Sand and dust was mainly deposited in spring and early summer in the study area. The weight of settled sand and dust collected during dust storms exhibited a positive correlation with the mean 10-min wind velocity (r2=0.60, n=16) during the dust storms. For the typical dust storms, the weight and flux of settled sand and dust will linearly increase with the increasing wind strength and fluctuation amplitude of wind velocities. The coarse fraction (N63 μm) also increases with them, in contrast, the finegrained fraction (b63 μm) decreases. It is plausible to assume that most of the fine-grained dust particles are lifted and transported far from the region under dust storm conditions, especially under the stronger and more variable wind conditions. The results demonstrate that the wind regime (strength and variability) is a key control on the sand and dust deposition during dust storm; dust can be emitted from the Qaidam Basin as one of dust source areas in China.

通过系统监测柴达木盆地北部冷湖地区的月降尘通量以及尘暴事件降尘量，发现该地区月降尘通量变化在0157×103～18112×103μg •cm -2•month-1之间，并且与月极大风速（Vextr）具有较好的正相关性（r2=0160，n=23）；该区年内主要粉尘堆积时段为春季和初夏；尘暴事件发生期间的降尘量不仅与尘暴持续期间10min平均风速具有良好的正相关关系（r2=0160，n=16），而且降尘量与10min风速变化幅度有关:强劲稳定的风力条件在监测地点产生较少的降尘量，强劲且变率较大的风力条件产生较多的降尘量。监测结果显示,风速的变化对粉尘的释放、输送和沉降有重要的影响,有助于理解地质记录所揭示的冰期- 间冰期不同的大气粉尘沉降速率。

通过对中卫剖面和米浪沟湾剖面的年代学与高分辨率气候地层记录的研究，认为末次冰消期东亚季风区西北缘发生气候快速变化事件，它可分辨出古仙女木、波令、老仙女木、阿勒鲁德、IACP和新仙女木等6个气候阶段，并可与格陵兰冰心（GISF'2）检出的6个气候阶段相对比。气候快速变化事件以快速变化、不稳定、多波动为特征，表现为冷干-暖湿冷干-凉湿-暖干冷干-冷湿的交替变化。冰消期冬、夏季风有较为复杂的消长关系，冰阶时二者互为消长、间冰阶时并不完全互为消长。冬季风在波令和阿勒鲁德暖期较新仙女木冷期强盛．这是北半球高纬度海区海冰面积在暖期缩小、冷期扩大而影响亚洲大陆蒙古-西伯利亚高压暖期增强、冷期减弱的结果；夏季风则与格陵兰冰心δ18O0的变化具有一致性，其强弱与北半球高纬地区有紧密联系，这种联系可能不是通过季风锋面降水带建立起来的，而可能是海冰面积变化导致厄尔尼诺南方涛动（ENSO）爆发造成的。

文章通过分析苏干湖表层沉积物、流域表层沉积物、大气降尘以及湖泊冰面囚固碎屑颗粒等的粒度组成，比较了流域地表沉积与湖泊沉积物粒度组成的差异和苏干湖表层沉积粒度组成的空间变化。初步认为苏干湖沉积物粗颗粒组分（>63μm）主要由风力搬运入湖，> 63μm组分的含量可以用来指示研究区尘暴事件的演化。结合湖泊沉积岩芯纹层计数年龄，重建的1000年来尘暴演化历史显示,在1210A. D. 之前尘暴事件较弱,且变化幅度较小；1210A. D. 以来则表现出高频率或者高强度,其中13世纪上半叶以及17世纪的高值段与东部降尘变化历史一致。就气候变化的特征时段（中世纪暖期、小冰期等）而言，尘暴事件主要与气候变冷情况下较强的盛行风场有关；而极端干旱区有效湿度的增加可能有利于地表粉尘的释放,助长了尘暴事件的发生。