Abstract
Abstract. While dust aerosols emitted from major Asian sources such as Taklimakan and Gobi deserts have been shown to have strong effect on Asian monsoon and climate, the role of dust emitted from Tibetan Plateau (TP) itself, where aerosols can directly interact with the TP heat pump because of their physical proximity both in location and elevation, has not been examined. This study uses the dust-coupled RegCM4.1 regional climate model (RCM) to simulate the spatiotemporal distribution of dust aerosols originating within the TP and their radiative effects on the East Asian summer monsoon (EASM) during both heavy and light dust years. Two 20-year simulations with and without the dust emission from TP showed that direct radiative cooling in the mid-troposphere induced by the TP locally produced dust aerosols resulted in an overall anticyclonic circulation anomaly in the low troposphere centered over the TP region. The northeasterly anomaly in the EASM region reduces its strength considerably. The simulations found a significant negative correlation between the TP column dust load produced by local emissions and the corresponding anomaly in the EASM index (r = −0.46). The locally generated TP dust can cause surface cooling far downstream in Bohai Gulf and the China–North Korea border area through stationary Rossby wave propagation. Although dust from within TP (mainly Qaidam Basin) is a relatively small portion of total Asian aerosols, its impacts on Asian monsoon and climate seems disproportionately large, likely owning to its higher elevation within TP itself.
Highlights
Dust is one of the most important components of atmospheric aerosols
The results from control experiment (CON) and sensitivity experiment (SEN) experiments will be compared to determine the roles of dust aerosols generated from the Tibetan Plateau (TP) play in the thermodynamic fields and circulations including the East Asian summer monsoon (EASM)
The simulated climatology can influence the distribution of dust aerosols and their climatic effects, so CON was used to analyze the surface temperature, precipitation and atmospheric circulation at 850 hPa
Summary
Dust is one of the most important components of atmospheric aerosols. Because of the large amount in the atmosphere, dust effects on the environment and the climate system have attracted much attention. Dust aerosols are important drivers of the global climate because of their direct radiative effects on the Earth–atmosphere radiation balance and temperature (Tegen and Lacis, 1996; Miller et al, 2004). They can alter the atmospheric hydrological cycle by acting as cloud condensation nuclei and can modulate both the regional and global precipitation (Rosenfeld et al, 2001). Satellite observations have shown that dust originating from the Taklimakan Desert can travel around the globe within 2 weeks and alter the interaction between the atmospheric CO2 and the global climate by providing nutrients to and interacting with the marine ecosystem (Uno et al, 2009)
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