Abstract
Abstract. International shipping emissions (ISE), particularly sulfur dioxide, can influence the global radiation budget by interacting with clouds and radiation after being oxidized into sulfate aerosols. A better understanding of the uncertainties in estimating the cloud radiative effects (CREs) of ISE is of great importance in climate science. Many international shipping tracks cover oceans with substantial natural dimethyl sulfide (DMS) emissions. The interplay between these two major aerosol sources on CREs over vast oceanic regions with a relatively low aerosol concentration is an intriguing yet poorly addressed issue confounding estimation of the CREs of ISE. Using an Earth system model including two aerosol modules with different aerosol mixing configurations, we derive a significant global net CRE of ISE (−0.153 W m−2 with a standard error of ±0.004 W m−2) when using emissions consistent with current ship emission regulations. This global net CRE would become much weaker and actually insignificant (−0.001 W m−2 standard error of ±0.007 W m−2) if a more stringent regulation were adopted. We then reveal that the ISE-induced CRE would achieve a significant enhancement when a lower DMS emission is prescribed in the simulations, owing to the sublinear relationship between aerosol concentration and cloud response. In addition, this study also demonstrates that the representation of certain aerosol processes, such as mixing states, can influence the magnitude and pattern of the ISE-induced CRE. These findings suggest a reevaluation of the ISE-induced CRE with consideration of DMS variability.
Highlights
Marine stratiform clouds have a strong cooling effect on the climate system
Note that International shipping emissions (ISE) contain a significant amount of black carbon (BC) and organic carbon (OC) aerosols, since this study mainly focuses on aerosol-induced cloud radiative effect (CRE) instead of aerosol direct radiative effect (DRE), we focus on only primary and secondary sulfate aerosols due to their much higher hygroscopicity than those of BC and OC aerosols (Pringle et al, 2010)
The magnitude of the total cooling effect is within the range from −50 to −10 mW m−2 estimated in previous studies (Endresen et al, 2003; Schreier et al, 2007)
Summary
Marine stratiform clouds have a strong cooling effect on the climate system. They cover about 30 % of the global ocean surface (Warren et al, 1988) and can reflect more solar radiation back to space than the dark ocean surface at cloudfree conditions. The international shipping-emitted sulfur dioxide from combustion of heavy fossil oil (Fig. 1) can be oxidized to sulfate aerosols that can increase cloud droplet number concentrations, cloud liquid water path, and planetary albedo, resulting in more solar radiation being reflected back to space, exerting a cooling effect on the climate system (Capaldo et al, 1999; Devasthale et al, 2006; Lauer et al, 2007, 2009). International shipping emissions (ISE) contribute only about 5 % (5.4 Tg S yr−1) to the total anthropogenic sulfur emissions
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