Dissemin is shutting down on January 1st, 2025

Published in

European Geosciences Union, Atmospheric Chemistry and Physics, 5(13), p. 2347-2379, 2013

DOI: 10.5194/acp-13-2347-2013

European Geosciences Union, Atmospheric Chemistry and Physics Discussions, 12(12), p. 32631-32706

DOI: 10.5194/acpd-12-32631-2012

Links

Tools

Export citation

Search in Google Scholar

Intercomparison of shortwave radiative transfer schemes in global aerosol modeling: results from the AeroCom Radiative Transfer Experiment

Journal article published in 2012 by C. A. Randles, GESTAR/Morgan State University, S. Kinne, Max Plank Institute for Meteorology, Finnish Meteorological Institute, University of Maryland Department of Atmospheric and Oceanic Science, G. Myhre ORCID, M. Schulz ORCID, Ludwig-Maximilians-Universitaet Munich, P. Stier ORCID, University of Vienna Fakultat fur Physik, J. Fischer, Lionel Doppler, Climate and Radiation Laboratory Nasa Gsfc, E. J. Highwood and other authors.
This paper is made freely available by the publisher.
This paper is made freely available by the publisher.

Full text: Download

Green circle
Preprint: archiving allowed
Green circle
Postprint: archiving allowed
Green circle
Published version: archiving allowed
Data provided by SHERPA/RoMEO

Abstract

Abstract. In this study we examine the performance of 31 global model radiative transfer schemes in cloud-free conditions with prescribed gaseous absorbers and no aerosols (Rayleigh atmosphere), with prescribed scattering-only aerosols, and with more absorbing aerosols. Results are compared to benchmark results from high-resolution, multi-angular line-by-line radiation models. For purely scattering aerosols, model bias relative to the line-by-line models in the top-of-the atmosphere aerosol radiative forcing ranges from roughly −10 to 20%, with over- and underestimates of radiative cooling at lower and higher solar zenith angle, respectively. Inter-model diversity (relative standard deviation) increases from ~10 to 15% as solar zenith angle decreases. Inter-model diversity in atmospheric and surface forcing decreases with increased aerosol absorption, indicating that the treatment of multiple-scattering is more variable than aerosol absorption in the models considered. Aerosol radiative forcing results from multi-stream models are generally in better agreement with the line-by-line results than the simpler two-stream schemes. Considering radiative fluxes, model performance is generally the same or slightly better than results from previous radiation scheme intercomparisons. However, the inter-model diversity in aerosol radiative forcing remains large, primarily as a result of the treatment of multiple-scattering. Results indicate that global models that estimate aerosol radiative forcing with two-stream radiation schemes may be subject to persistent biases introduced by these schemes, particularly for regional aerosol forcing.