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Poster Title

Dust Life Cycle and Direct Radiative Effects in E3SMv1

Authors

Yan FengHailong WangRichard Easter (Unlicensed),Wuyin Lin, Kai Zhang,Po-Lun Ma,Phil Rasch (pnl.gov), Shaocheng Xie, Jasper Kok, Natalie Mahowald, and Hongbin Yu

First AuthorYan Feng
Session TypeE3SM session
Session IDE9
Submission Type'poster' or 'presentation'Poster
GroupWater cycle
ExperimentWater cycle, BGC
Poster Link




Abstract

A recent study of CMIP5 models (Kok et al., 2018) shows the direct climate feedback by dust aerosols is about -0.04 to +0.02 Wm-2K-1, which accounts for a significant fraction of the direct climate feedback by all aerosols. Dust is also a major source of ice nuclei for aerosol indirect effects and supplies the key nutrients (iron/phosphorus) to the open ocean. Therefore, quantification of dust life cycle and radiative effects in E3SMv1 has important implications on both the water cycle and biogeochemical simulations in response to climate change. Here we focused on evaluation of the simulated dust distributions for estimating dust direct radiative effects under the present-day conditions. The impact of increasing model resolution on dust simulations is also examined.

The calculated global and annual mean dust aerosol optical depth (AOD) is 0.026 and 0.03 in the low- (~1 degree) and high- (~0.25 degree) resolution E3SMv1, respectively. The model estimates of global dust AOD are similar independent of resolution, because dust model estimates of global dust AOD are similar independent of resolution between the low- and high- resolution E3SMv1 models (0.026 vs 0.03), since the dust emissions are tuned to match the observational constraint of global dust AOD at 0.03±0.01. Yet, there are still substantial differences in the predicted dust AOD distributions depending on the model resolution, i.e., about 5 times differences over the Taklimakan desert. The changes in dust AOD are more than ±10% near the major dust source regions or downwind, resulting from local changes of dust emissions, dry and wet removal efficiencies due to increase of the resolved spatial scales. They could further affect the simulated regional energy balance, especially in the dust-influenced high latitudes where the climate sensitivity to dust forcing is large. Compared to the 10-year ground-based AERONET observations of AOD, the low-resolution E3SMv1 underpredicts the total AOD by about 31% averaged over the 247 AERONET sites. However, the underestimation of AOD is mainly due to aerosol predictions in Asia associated with the anthropogenic emissions (year 2000). Over the selected 14 ‘dusty’ AERONET sites, the modeled mean AOD (0.299) agrees well with the AERONET data (0.311), for a correlation coefficient of 0.91. The vertical distribution of dust is compared with the CALIPSO satellite-retrieved profiles, indicating an underestimation of dust vertical transport. This is related to the short lifetime of dust simulated by the E3SMv1 for less than 2 days, due to excessive dry and wet dust removals compared with other global climate models.

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