Abstract
This investigation focuses on the characterisation of the aerosol particle hygroscopicity. Aerosol particle optical properties were measured at Granada, Spain, during winter and spring seasons in 2013. Measured optical properties included particle light-absorption coefficient (σap) and particle light-scattering coefficient (σsp) at dry conditions and at relative humidity (RH) of 85±10%. The scattering enhancement factor, f(RH=85%), had a mean value of 1.5±0.2 and 1.6±0.3 for winter and spring campaigns, respectively. Cases of high scattering enhancement were more frequent during the spring campaign with 27% of the f(RH=85%) values above 1.8, while during the winter campaign only 8% of the data were above 1.8. A Saharan dust event (SDE), which occurred during the spring campaign, was characterised by a predominance of large particles with low hygroscopicity. For the day when the SDE was more intense, a mean daily value of f(RH=85%)=1.3±0.2 was calculated. f(RH=85%) diurnal cycle showed two minima during the morning and afternoon traffic rush hours due to the increase in non-hygroscopic particles such as black carbon and road dust. This was confirmed by small values of the single-scattering albedo and the scattering Ångstrom exponent. A significant correlation between f(RH=85%) and the fraction of particulate organic matter and sulphate was obtained. Finally, the impact of ambient RH in the aerosol radiative forcing was found to be very small due to the low ambient RH. For high RH values, the hygroscopic effect should be taken into account since the aerosol forcing efficiency changed from −13 W/m2 at dry conditions to −17 W/m2 at RH=85%.
Highlights
Aerosol particles, both natural and anthropogenic, are radiatively active components of the Earth’s atmosphere
We describe a recently build humidification system for a nephelometer that allows the determination of f(RH)
Two measurement campaigns were conducted in Granada during the winter and spring seasons to study the aerosol particle scattering enhancement due to water uptake
Summary
Both natural and anthropogenic, are radiatively active components of the Earth’s atmosphere. Numerous works have investigated the change in size of aerosol particles due to water uptake by means of Humidified Tandem Differential Mobility Analyzers (HTDMAs) (Massling et al, 2007; Meier et al, 2009; Wu et al, 2013, and references therein) Some of these works include theoretical calculations using Mie theory to quantify the effect that this growth in size may have in the scattering coefficient, which is of more climatic relevance. The combination of both measurements allows the determination of the scattering enhancement factor [f(RH)], that is, the ratio between the scattering coefficient at a certain RH and the scattering coefficient at dry conditions This factor quantifies the amount of change in the particle light-scattering coefficient due to water uptake. The relationships between f(RH), chemical composition and intensive aerosol parameters, such as the aerosol single-scattering albedo or the scattering coefficient related Angstrom exponent, are explored
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