Abstract
Abstract. Both frequency and intensity of rainfall affect aerosol wet deposition. With a stochastic deep convection scheme implemented into two state-of-the-art global climate models (GCMs), a recent study found that aerosol burdens are increased globally by reduced climatological mean wet removal of aerosols due to suppressed light rain. Motivated by their work, a novel approach is developed in this study to detect what rainfall rates are most efficient for wet removal (scavenging amount mode) of different aerosol species of different sizes in GCMs and applied to the National Center for Atmospheric Research Community Atmosphere Model version 5 (CAM5) with and without the stochastic convection cases. Results show that in the standard CAM5, no obvious differences in the scavenging amount mode are found among different aerosol types. However, the scavenging amount modes differ in the Aitken, accumulation and coarse modes, showing around 10–12, 8–9 and 7–8 mm d−1, respectively, over the tropics. As latitude increases poleward, the scavenging amount mode in each aerosol mode is decreased substantially. The scavenging amount mode is generally smaller over land than over ocean. With stochastic convection, the scavenging amount mode for all aerosol species in each mode is systematically increased, which is the most prominent along the Intertropical Convergence Zone, exceeding 20 mm d−1 for small particles. The scavenging amount modes in the two cases are both smaller than individual rainfall rates associated with the most accumulated rain (rainfall amount mode), further implying precipitation frequency is more important than precipitation intensity for aerosol wet removal. The notion of the scavenging amount mode can be applied to other GCMs to better understand the relation between rainfall and aerosol wet scavenging, which is important to better simulate aerosols.
Highlights
Wet deposition through scavenging by rainfall is an important sink for atmospheric aerosols and soluble gases (Atlas and Giam, 1988; Radke et al, 1980)
Mahowald et al (2011) explored the role of precipitation frequency in dust wet deposition based on model simulations and noted the frequency of precipitation rather than the amount of precipitation controls the fraction of dust wet vs. dry deposition outside dust source regions
This study develops a novel approach to identify the rainfall intensity associated with the most efficient aerosol wet scavenging and applies it to different aerosol species at different aerosol sizes in the National Center for Atmospheric Research (NCAR) Community Atmosphere Model version 5 (CAM5)
Summary
Wet deposition through scavenging by rainfall is an important sink for atmospheric aerosols and soluble gases (Atlas and Giam, 1988; Radke et al, 1980). Dawson et al (2007) found a strong sensitivity of concentrations of the particulate matter with a diameter less than 2.5 μm (PM2.5) to rainfall intensity over a large region of the eastern United States from sensitivity tests using a regional numerical model. In the Geophysical Fluid Dynamics Laboratory (GFDL) chemistryclimate model AM3, Fang et al (2011) found wet scavenging has a stronger spatial correlation with rainfall frequency than intensity over the United States in January. In the Geophysical Fluid Dynamics Laboratory (GFDL) chemistryclimate model AM3, Fang et al (2011) found wet scavenging has a stronger spatial correlation with rainfall frequency than intensity over the United States in January. Mahowald et al (2011) explored the role of precipitation frequency in dust wet deposition based on model simulations and noted the frequency of precipitation rather than the amount of precipitation controls the fraction of dust wet vs. dry deposition outside dust source regions
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