Abstract
Abstract. We present a sensitivity study of the effects of spatial and temporal resolution of atmospheric relative humidity (RH) on calculated aerosol optical thickness (AOT) and the aerosol direct radiative effects (DRE) in a global model. We carry out different modeling experiments using the same aerosol fields simulated in the Global Modeling Initiative (GMI) model at a resolution of 2° latitude by 2.5° longitude, using time-averaged fields archived every three hours by the Goddard Earth Observation System Version 4 (GEOS-4), but we change the horizontal and temporal resolution of the relative humidity fields. We find that, on a global average, the AOT calculated using RH at a 1°×1.25° horizontal resolution is 11% higher than that using RH at a 2°×2.5° resolution, and the corresponding DRE at the top of the atmosphere is 8–9% and 15% more negative (i.e., more cooling) for total aerosols and anthropogenic aerosol alone, respectively, in the finer spatial resolution case. The difference is largest over surface escarpment regions (e.g. >200% over the Andes Mountains) where RH varies substantially with surface terrain. The largest zonal mean AOT difference occurs at 50–60° N (16–21%), where AOT is also relatively larger. A similar impact is also found when the time resolution of RH is increased. This increase of AOT and aerosol cooling with the increase of model resolution is due to the highly non-linear relationship between RH and the aerosol mass extinction efficiency (MEE) at high RH (>80%). Our study is a specific example of the uncertainty in model results highlighted by multi-model comparisons such as AeroCom, and points out one of the many inter-model differences that can contribute to the overall spread among models.
Highlights
Relative humidity (RH) can significantly influence ambient aerosol optical thickness (AOT) and, aerosol direct radiative forcing (Kinne et al, 2003; Malm et al, 2005; Pahlow et al, 2006; Wang et al, 2008)
Since the aerosol optical thickness (AOT) is determined by the product of aerosol dry mass and the mass extinction efficiency (MEE), a non-linear relationship between MEE and relative humidity (RH) will translate into non-linearity in AOT and a dependence on the RH resolution used in the model
We present and discuss the relationship between AOT and RH in terms of the change in the RH horizontal and temporal resolution
Summary
Relative humidity (RH) can significantly influence ambient aerosol optical thickness (AOT) and, aerosol direct radiative forcing (Kinne et al, 2003; Malm et al, 2005; Pahlow et al, 2006; Wang et al, 2008). Accounting for the impact of RH on AOT in chemistry transport model (CTM) simulations requires a good simulation of moisture field by the underlying General Circulation Model (GCM) and consideration of spatial and temporal resolution of the RH field because this field exhibits large heterogeneity in both space and time. This issue of RH representation is directly relevant to the work of AeroCom (Aerosol Comparison between Observations and Models), a model intercomparison effort to assess aerosol properties and their atmospheric effects, which includes models with different spatial resolutions (Kinne et al, 2006; Schulz et al, 2006; Textor et al, 2006). Due to this non-linear relationship, the sub-grid RH variation will inevitably yield difference among AOTs which are calculated using different spatial (or temporal) averages for RHs, even if the RHs originate from the same GCM
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