Surprising similarities in model and observational aerosol radiative forcing estimates.

Edward Gryspeerdt,Daniel G Partridge,Johannes Mülmenstädt,Hugh Morrison,Minghuai Wang,Andrew Gettelman,Toshihiko Takemura,Kai Zhang,Hailong Wang,Florent F Malavelle,David Neubauer,Philip Stier

doi:10.5194/acp-20-613-2020

Abstract

The radiative forcing from aerosols (particularly through their interaction with clouds) remains one of the most uncertain components of the human forcing of the climate. Observation-based studies have typically found a smaller aerosol effective radiative forcing than in model simulations and were given preferential weighting in the Intergovernmental Panel on Climate Change (IPCC) Fifth Assessment Report (AR5). With their own sources of uncertainty, it is not clear that observation-based estimates are more reliable. Understanding the source of the model and observational differences is thus vital to reduce uncertainty in the impact of aerosols on the climate.These reported discrepancies arise from the different methods of separating the components of aerosol forcing used in model and observational studies. Applying the observational decomposition to global climate model (GCM) output, the two different lines of evidence are surprisingly similar, with a much better agreement on the magnitude of aerosol impacts on cloud properties. Cloud adjustments remain a significant source of uncertainty, particularly for ice clouds. However, they are consistent with the uncertainty from observation-based methods, with the liquid water path adjustment usually enhancing the Twomey effect by less than 50%. Depending on different sets of assumptions, this work suggests that model and observation-based estimates could be more equally weighted in future synthesis studies.

Highlights

Acting as cloud condensation nuclei (CCN) and ice nucleating particles (INPs), aerosols can modify the cloud droplet number concentration (Nd) and the ice crystal number concentration (Ni)
An increase in Nd can impact the reflectivity of a cloud (Twomey, 1974), resulting in a cooling effect on the climate known as the radiative forcing from aerosol– cloud interactions (RFaci) or the “Twomey effect”
The sign and magnitude of the forcing from cloud adjustments are highly uncertain (Han et al, 2002; Seifert et al, 2015; Gryspeerdt et al, 2016; Malavelle et al, 2017; McCoy et al, 2018), and this uncertainty is a leading contributor to uncertainty in the overall effective radiative forcing from aerosols (ERFaer)

Summary

Introduction

Acting as cloud condensation nuclei (CCN) and ice nucleating particles (INPs), aerosols can modify the cloud droplet number concentration (Nd) and the ice crystal number concentration (Ni). An increase in Nd can impact the reflectivity of a cloud (Twomey, 1974), resulting in a cooling effect on the climate known as the radiative forcing from aerosol– cloud interactions (RFaci) or the “Twomey effect”. An aerosol-induced change in Ni may change ice-cloud properties. The combination of these adjustments and the RFaci is known as the effective radiative forcing from aerosol–cloud interactions (ERFaci). The sign and magnitude of the forcing from cloud adjustments are highly uncertain (Han et al, 2002; Seifert et al, 2015; Gryspeerdt et al, 2016; Malavelle et al, 2017; McCoy et al, 2018), and this uncertainty is a leading contributor to uncertainty in the overall effective radiative forcing from aerosols (ERFaer)

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Conclusion