Abstract
Abstract. Atmospheric aerosol composition was measured using a Single Particle Soot Photometer (SP2) in the Finnish Arctic during winter 2011–2012. The Sammaltunturi measurement site at the Pallas GAW (Global Atmosphere Watch) station receives air masses from different source regions including the Arctic Ocean and continental Europe. The SP2 provides detailed information about mass distributions and mixing state of refractory black carbon (rBC). The measurements showed widely varying rBC mass concentrations (0–120 ng m−3), which were related to varying contributions of different source regions and aerosol removal processes. The rBC mass was log-normally distributed showing a relatively constant rBC core mass mean diameter with an average of 194 nm (75–655 nm sizing range). On average, the number fraction of particles containing rBC was 0.24 (integrated over 350–450 nm particle diameter range) and the average particle diameter to rBC core volume equivalent diameter ratio was 2.0 (averaged over particles with 150–200 nm rBC core volume equivalent diameters). These average numbers mean that the observed rBC core mass mean diameter is similar to those of aged particles, but the observed particles seem to have unusually high particle to rBC core diameter ratios. Comparison of the measured rBC mass concentration with that of the optically detected equivalent black carbon (eBC) using an Aethalometer and a MAAP showed that eBC was larger by a factor of five. The difference could not be fully explained without assuming that only a part of the optically detected light absorbing material is refractory and absorbs light at the wavelength used by the SP2. Finally, climate implications of five different black carbon mixing state representations were compared using the Mie approximation and simple direct radiative forcing efficiency calculations. These calculations showed that the observed mixing state means significantly lower warming effect or even a net cooling effect when compared with that of a homogenous aerosol containing the same amounts of black carbon and non-absorbing material.
Highlights
Atmospheric aerosols scatter incoming solar radiation and have a cooling effect on climate, but certain aerosol species such as black carbon absorb solar radiation, which means that they can have a warming effect (IPCC, 2013; Bond et al, 2013)
Atmospheric general circulation models are used to quantify climate effects of black carbon (BC) aerosols, but it is known that these models are not accurate in simulating the complex aerosol lifecycles including formation, aging, transportation, cloud interactions, and removal processes
The main purpose of this study is to provide new experimental information about the refractory black carbon (rBC) mass distributions and mixing state in the Finnish Arctic
Summary
Atmospheric aerosols scatter incoming solar radiation and have a cooling effect on climate, but certain aerosol species such as black carbon absorb solar radiation, which means that they can have a warming effect (IPCC, 2013; Bond et al, 2013). Atmospheric general circulation models are used to quantify climate effects of black carbon (BC) aerosols, but it is known that these models are not accurate in simulating the complex aerosol lifecycles including formation, aging, transportation, cloud interactions, and removal processes Wang et al, 2014) This means that the model predicted aerosol concentrations and mixing state are generally not in agreement with the observations.
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