Abstract
Satellite aerosol and cloud climate data records (CDRs) have been used successfully to study the aerosol indirect effect (AIE). Data from the Advanced Very High Resolution Radiometer (AVHRR) now span more than 30 years and allow these studies to be conducted from a climatology perspective. In this paper, AVHRR data are used to study the AIE on water clouds over the global oceans. Correlation analysis between aerosol optical thickness (AOT) and cloud parameters, including cloud droplet effective radius (CDER), cloud optical depth (COD), cloud water path (CWP), and cloud cover fraction (CCF), is performed. For the first time from satellite observations, the long-term trend in AIE over the global oceans is also examined. Three regimes have been identified: (1) AOT < 0.08, where CDER increases with AOT; (2) 0.08 < AOT < 0.3, where CDER generally decreases when AOT increases; and (3) AOT > 0.3, where CDER first increases with AOT and then levels off. AIE is easy to manifest in the CDER reduction in the second regime (named Regime 2), which is identified as the AIE sensitive/effective regime. The AIE manifested in the consistent changes of all four cloud variables (CDER, COD, CWP, and CCF) together is located only in limited areas and with evident seasonal variations. The long-term trend of CDER changes due to the AIE of AOT changes is detected and falls into three scenarios: Evident CDER decreasing (increasing) with significant AOT increasing (decreasing) and evident CDER decreasing with limited AOT increasing but AOT values fall in the AIE sensitive Regime 2.
Highlights
Cloud microphysical structures and properties play an important role in the cloud-radiativeprecipitation feedbacks and provide a critical link between the energy and hydrological cycles ofEarth’s climate system
Changes in atmospheric aerosols due to anthropogenic emissions will result in the modification of cloud condensation nuclei (CCN) and cloud microphysical properties, which will further change the cloud effect on the radiation budget and precipitation efficiency
In order to evaluate aerosol indirect effect (AIE) of water clouds over global ocean using the satellite observation, we analyze the correlations between aerosol optical thickness (AOT), which is considered as a proxy of column aerosol concentration [9,28,33,36,37,73], and cloud parameters, including cloud droplet effective radius (CDER), cloud optical depth (COD), cloud water path (CWP), and cloud cover fraction (CCF)
Summary
Cloud microphysical structures and properties play an important role in the cloud-radiativeprecipitation feedbacks and provide a critical link between the energy and hydrological cycles ofEarth’s climate system. Atmospheric aerosol in the accumulation mode is the major source of cloud condensation nuclei and is critical for the formation of cloud microphysical structures and properties [1,2,3]. Changes in atmospheric aerosols due to anthropogenic emissions will result in the modification of CCN and cloud microphysical properties, which will further change the cloud effect on the radiation budget and precipitation efficiency. This entire process is named as the aerosol indirect effect (AIE) [4,5,6,7,8,9,10]
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