Schulz, M. and Textor, C. and Kinne, S. and Balkanski, Y. and Bauer, S. and Bertsen, T. and Berglen, T. and Boucher, O. and Dentener, F. and Guibert, S. and Isaksen, I. S. A. and Iversen, T. and Koch, D. and Kirkevåg, A. and Liu, X. and Montanaro, V. and Myhre, G. and Penner, J. E. and Pitari, G. and Reddy, S. and Seland, Ø. and Stier, P. and Takemura, T. (2006) Radiative forcing by aerosols as derived from the AeroCom present-day and pre-industrial simulations. Atmospheric Chemistry and Physics Discussions, 6 (3). pp. 5095-5136. ISSN 1680-7367 http://resolver.caltech.edu/CaltechAUTHORS:SCHUacpd06
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Nine different global models with detailed aerosol modules have independently produced instantaneous direct radiative forcing due to anthropogenic aerosols. The anthropogenic impact is derived from the difference of two model simulations with identically prescribed aerosol emissions, one for present-day and one for pre-industrial conditions. The difference in the energy budget at the top of the atmosphere (ToA) yields a new harmonized estimate for the aerosol direct radiative forcing (RF) under all-sky conditions. On a global annual basis RF is –0.2 Wm^-2, with a standard deviation of ±0.2 Wm^-2. Anthropogenic nitrate and dust are not included in this estimate. No model shows a significant positive all-sky RF. The corresponding clear-sky RF is –0.6 Wm^-2. The cloud-sky RF was derived based on all-sky and clear-sky RF and modelled cloud cover. It was significantly different from zero and ranged between –0.16 and +0.34 Wm^-2. A sensitivity analysis shows that the total aerosol RF is influenced by considerable diversity in simulated residence times, mass extinction coefficients and most importantly forcing efficiencies (forcing per unit optical depth). Forcing efficiency differences among models explain most of the variability, mainly because all-sky forcing estimates require proper representation of cloud fields and the correct relative altitude placement between absorbing aerosol and clouds. The analysis of the sulphate RF shows that differences in sulphate residence times are compensated by opposite mass extinction coefficients. This is explained by more sulphate particle humidity growth and thus higher extinction in models with short-lived sulphate present at lower altitude and vice versa. Solar absorption within the atmospheric column is estimated at +0.85 Wm^-2. The local annual average maxima of atmospheric forcing exceed +5 Wm^-2 confirming the regional character of aerosol impacts on climate. The annual average surface forcing is –1.03 Wm^-2.
|Additional Information:||© 2006 Author(s). This work is licensed under a Creative Commons License. Published by Copernicus GmbH on behalf of the European Geosciences Union. Received: 25 April 2006 – Accepted: 11 May 2006 – Published: 22 June 2006. This work was among others supported by the European Project PHOENICS (Particles of Human Origin Extinguishing “natural” solar radiation In Climate Systems) under grant EVK2-CT-2001-00098. The authors would like to thank the Laboratoire des Sciences du Climat et de l’Environnement/IPSL, Gif-sur-Yvette, France, and the Max-Planck-Institut für Meteorologie, Hamburg, Germany for support in hosting the AeroCom database.|
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|Deposited On:||31 Jan 2007|
|Last Modified:||26 Dec 2012 09:30|
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