Abstract
The aerosol-climate modelling system ECHAM5-
HAM is introduced. It is based on a flexible microphysical
approach and, as the number of externally imposed parameters
is minimised, allows the application in a wide range of
climate regimes. ECHAM5-HAM predicts the evolution of
an ensemble of microphysically interacting internally- and
externally-mixed aerosol populations as well as their sizedistribution
and composition. The size-distribution is represented
by a superposition of log-normal modes. In the
current setup, the major global aerosol compounds sulfate
(SU), black carbon (BC), particulate organic matter (POM),
sea salt (SS), and mineral dust (DU) are included. The simulated
global annual mean aerosol burdens (lifetimes) for the
year 2000 are for SU: 0.80 Tg(S) (3.9 days), for BC: 0.11
Tg (5.4 days), for POM: 0.99 Tg (5.4 days), for SS: 10.5
Tg (0.8 days), and for DU: 8.28 Tg (4.6 days). An extensive
evaluation with in-situ and remote sensing measurements underscores
that the model results are generally in good agreement
with observations of the global aerosol system. The
simulated global annual mean aerosol optical depth (AOD)
is with 0.14 in excellent agreement with an estimate derived
from AERONET measurements (0.14) and a composite derived
from MODIS-MISR satellite retrievals (0.16). Regionally,
the deviations are not negligible. However, the main
patterns of AOD attributable to anthropogenic activity are reproduced.
Original language | English |
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Pages (from-to) | 1125-1156 |
Journal | Atmospheric Chemistry and Physics |
Volume | 2005 |
Issue number | 5 |
Publication status | Published - 2005 |
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