Abstract
Abstract. Aerosol–cloud interaction effects are a major source of uncertainty in climate models so it is important to quantify the sources of uncertainty and thereby direct research efforts. However, the computational expense of global aerosol models has prevented a full statistical analysis of their outputs. Here we perform a variance-based analysis of a global 3-D aerosol microphysics model to quantify the magnitude and leading causes of parametric uncertainty in model-estimated present-day concentrations of cloud condensation nuclei (CCN). Twenty-eight model parameters covering essentially all important aerosol processes, emissions and representation of aerosol size distributions were defined based on expert elicitation. An uncertainty analysis was then performed based on a Monte Carlo-type sampling of an emulator built for each model grid cell. The standard deviation around the mean CCN varies globally between about ±30% over some marine regions to ±40–100% over most land areas and high latitudes, implying that aerosol processes and emissions are likely to be a significant source of uncertainty in model simulations of aerosol–cloud effects on climate. Among the most important contributors to CCN uncertainty are the sizes of emitted primary particles, including carbonaceous combustion particles from wildfires, biomass burning and fossil fuel use, as well as sulfate particles formed on sub-grid scales. Emissions of carbonaceous combustion particles affect CCN uncertainty more than sulfur emissions. Aerosol emission-related parameters dominate the uncertainty close to sources, while uncertainty in aerosol microphysical processes becomes increasingly important in remote regions, being dominated by deposition and aerosol sulfate formation during cloud-processing. The results lead to several recommendations for research that would result in improved modelling of cloud–active aerosol on a global scale.
Highlights
Systems model-estimated present-day concentrations of cloud condensation nuclei (CCN)
The CCN and sensitivity maps are produced from an analysis of 8192 independent emulators, and yet we find that the spatial patterns can be readily understood in terms of the driving processes, implying that the emulator mean is not dominated by its uncertainty in the different grid boxes
We have used an ensemble of global aerosol microphysics simulations together with emulators and variance-based sensitivity analysis to quantify the magnitude and causes of uncertainty in monthly-mean CCN for every 2.8◦ grid box of a global aerosol model at the altitude of 915 hPa
Summary
Methods and Data Systems model-estimated present-day concentrations of cloud condensation nuclei (CCN). Twenty-eight model parameters Successive Intergovernmental Panel on Climate Change covering essentially all important aerosol processes, emissions and representation of aerosol size distributions were defined based on expert elicitation. Global aerosols can impact the pling of an emulator built for each model grid cell. The climate in two distinct ways: the direct radiative effect is a restandard deviation around the mean CCN varies globally sult of atmospheric aeroHsoylsdrerfloelcotigngyoraanbsdorbing solar rabetween about ±30 % over some marine regions to ±40– 100 % over most land areas and high latitudes, implying that aerosol processes and emissions are likely to be a signifidTihaetioinndiarnedcttehfefreecbtyrecfoeorslitEnogathorertmwhaarnSmyyiwnsgayttesheimncwlimhiactheaseyrsotseomls. Interact with clouds, leading to cShacngieesnincderosplet concentracant source of uncertainty in model simulations of aerosol– tions, cloud albedo and precipitation
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
