A. J. van Beelen scite author profile

Abstract. Remote sensing of aerosols provides important information on atmospheric aerosol abundance. However, due to the hygroscopic nature of aerosol particles observed aerosol optical properties are influenced by atmospheric humidity, and the measurements do not unambiguously characterize the aerosol dry mass and composition, which complicates the comparison with aerosol models. In this study we derive aerosol water and chemical composition by a modeling approach that combines individual measurements of remotely sensed aerosol properties (e.g., optical thickness, single-scattering albedo, refractive index and size distribution) from an AERONET (Aerosol Robotic Network) Sunsky radiometer with radiosonde measurements of relative humidity. The model simulates water uptake by aerosols based on the chemical composition (e.g., sulfates, ammonium, nitrate, organic matter and black carbon) and size distribution. A minimization method is used to calculate aerosol composition and concentration, which are then compared to in situ measurements from the Intensive Measurement Campaign At the Cabauw Tower (IMPACT, May 2008, the Netherlands). Computed concentrations show good agreement with campaign-average (i.e., 1-14 May) surface observations (mean bias is 3 % for PM 10 and 4-25 % for the individual compounds). They follow the day-to-day (synoptic) variability in the observations and are in reasonable agreement for daily average concentrations (i.e., mean bias is 5 % for PM 10 and black carbon, 10 % for the inorganic salts and 18 % for organic matter; root-mean-squared deviations are 26 % for PM 10 and 35-45 % for the individual compounds).The modeled water volume fraction is highly variable and strongly dependent on composition. During this campaign we find that it is > 0.5 at approximately 80 % relative humidity (RH) when the aerosol composition is dominated by hygroscopic inorganic salts, and < 0.1 when RH is below 40 %, especially when the composition is dominated by less hygroscopic compounds such as organic matter. The scattering enhancement factor (f(RH), the ratio of the scattering coefficient at 85 % RH and its dry value at 676 nm) during 1-14 May is 2.6 ± 0.5. The uncertainty in AERONET (real) refractive index (0.025-0.05) is the largest source of uncertainty in the modeled aerosol composition and leads to an uncertainty of 0.1-0.25 (50-100 %) in aerosol water volume fraction. Our methodology performs relatively well at Cabauw, but a better performance may be expected for regions with higher aerosol loading where the uncertainties in the AERONET inversions are smaller.

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Cleaner air brings better views, more sunshine and warmer summer days in the Netherlands

Beelen

Delden

2012

Weather

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Estimation of aerosol water and chemical composition from AERONET at Cabauw, the Netherlands

Beelen¹,

Roelofs²,

Hasekamp³

et al. 2013

Preprint

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Remote sensing of aerosols provides important information on the atmospheric aerosol abundance. However, due to the hygroscopic nature of aerosol particles observed aerosol optical properties are influenced by atmospheric humidity, and the measurements do not unambiguously characterize the aerosol dry mass and composition which complicates the comparison with aerosol models. In this study we derive aerosol water and chemical composition by a modeling approach that combines individual measurements of remotely sensed aerosol properties (e.g. optical thickness, single scattering albedo, refractive index and size distribution) from an AERONET (Aerosol Robotic Network) sun-photometer with radiosonde measurements of relative humidity. The model simulates water uptake by aerosols based on the chemical composition and size distribution. A minimization method is used to calculate aerosol composition and concentration, which are then compared to in situ measurements from the Intensive Measurement Campaign At the Cabauw Tower (IMPACT, May 2008, the Netherlands). Computed concentrations show reasonable agreement with surface observations and follow the day-to-day variability in observations. Total dry mass (33 ± 12 μg m⁻³) and black carbon concentrations (0.7 ± 0.3 μg m⁻³) are generally accurately computed. The uncertainty in the AERONET (real) refractive index (0.025–0.05) introduces larger uncertainty in the modeled aerosol composition (e.g. sulfates, ammonium nitrate or organic matter) and leads to an uncertainty of 0.1–0.25 in aerosol water volume fraction. Water volume fraction is highly variable depending on composition, up to >0.5 at 70–80% and <0.1 at 40% relative humidity

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A. J. van Beelen

Estimation of aerosol water and chemical composition from AERONET Sun–sky radiometer measurements at Cabauw, the Netherlands

Cleaner air brings better views, more sunshine and warmer summer days in the Netherlands

Estimation of aerosol water and chemical composition from AERONET at Cabauw, the Netherlands

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