Showing papers by "Lide Tian published in 2010"

Dust concentration and flux in ice cores from the Tibetan Plateau over the past few decades

Abstract: In this paper, we provide the concentrations and fluxes of dust particles (1–30 μm diameter), quantitatively calculated, in several shallow ice cores recovered from the northern (Dunde), western (Muztagata), central (Tanggula) and southern (Dasuopu and Everest) parts of the Tibetan Plateau over the past few decades. Dust concentrations from the northern and western Tibetan Plateau are 2–10 times higher, and from the central Tibetan Plateau is five times higher, respectively, than in the southern part. Dust flux in ice cores is highly dependent on mass concentration, but does not necessarily correlate with accumulation. Dust flux in Dunde (about 798 μg cm -2 a -1 ) is 10 times higher, and that in Muztagata (342 μg cm -2 a -1 ) is four times higher, respectively, than the dust flux in the central Himalayas (77–103 μg cm -2 a -1 ). The quantitative assessment of dust flux in ice cores accords with the aerosol optical depth, and both suggest that the general dust transport route is from northwest to southeast over the Tibetan Plateau. Our results reveal the basic properties of upper level tropospheric dust over the Tibetan Plateau, which is useful for the study of the climatic effects of this dust. DOI: 10.1111/j.1600-0889.2010.00457.x

Characterization of precipitation δ 18 O variation in Nagqu, central Tibetan Plateau and its climatic controls

Abstract: The stable isotopic composition of precipitation in different regions reflects climatic factors such as temperature, precipitation, moisture sources, and transport process. However, the isotopic variation in the region is usually much complicated due to the combined influences of these factors. A good understanding of climatic controls on the isotopic composition of precipitation can contribute to the study on isotopic tracer for climate and hydrology. To investigate the isotopic variation of precipitation and its climatic controls in the middle of the Tibetan Plateau, a monitoring station for stable isotope in precipitation has been established in Nagqu region, central Tibetan Plateau. We obtained 79 daily samples at Nagqu Meteorological Station in 2000. The observed δ18O in precipitation showed a distinctly seasonal pattern with higher values in spring and winter and lower values in summer, despite of individually low values in winter due to extremely low temperature. To further understand this pattern, we evaluated the influence of temperature, precipitation, moisture sources, and moisture transport process on precipitation δ18O. A multiple linear regression model represents quantitatively the dependence of precipitation δ18O on precipitation and temperature: δ18Oppt = −0.30P − 0.11T − 14.8 (R2 = 0.13, n = 79, P = 0.005), which indicates δ18O values in precipitation are more dependent on precipitation amount than on temperature. In contrast, when the temperature is low enough (<2°C), δ18O values in precipitation are mainly dependent on temperature: δ18Oppt = 0.53T − 10.2 (R2 = 0.44, n = 19, P = 0.002). The variation of δ18O in precipitation is also closely related to moisture origins and transport trajectories. A model is set up to trace the trajectories for air masses arriving in the observed region, and the results demonstrated that humid marine air masses from the Indian Ocean generally have significantly lower δ18O values than dry continental air masses from the north or local re-evaporation. During monsoon precipitation, the distance and depth of moisture transport as well as convective precipitation all lead to the large variability of δ18O in precipitation.