Abstract
Abstract. Aerosols influence the Earth's radiation budget directly through absorption and scattering of solar radiation in the atmosphere but also indirectly by modifying the properties of clouds. However, climate models still suffer from large uncertainties as a result of insufficient understanding of aerosol-cloud interactions. At the high altitude research station Jungfraujoch (JFJ; 3580 m a.s.l., Switzerland) cloud condensation nuclei (CCN) number concentrations at eight different supersaturations (SS) from 0.24% to 1.18% were measured using a CCN counter during Summer 2011. Simultaneously, in-situ aerosol activation properties of the prevailing ambient clouds were investigated by measuring the total and interstitial (non-activated) dry particle number size distributions behind two different inlet systems. Combining all experimental data, a new method was developed to retrieve the so-called effective peak supersaturation SSpeak, as a measure of the SS at which ambient clouds are formed. A 17-month CCN climatology was then used to retrieve the SSpeak values also for four earlier summer campaigns (2000, 2002, 2004 and 2010) where no direct CCN data were available. The SSpeak values varied between 0.01% and 2.0% during all campaigns. An overall median SSpeak of 0.35% and dry activation diameter of 87 nm was observed. It was found that the difference in topography between northwest and southeast plays an important role for the effective peak supersaturation in clouds formed in the vicinity of the JFJ, while differences in the number concentration of potential CCN only play a minor role. Results show that air masses coming from the southeast (with the slowly rising terrain of the Aletsch Glacier) generally experience lower SSpeak values than air masses coming from the northwest (steep slope). The observed overall median values were 0.41% and 0.22% for northwest and southeast wind conditions, respectively, corresponding to literature values for cumulus clouds and shallow-layer clouds. These cloud types are consistent with weather observations routinely performed at the JFJ.
Highlights
Cloud droplets may form when aerosol particles are exposed to air that is supersaturated with respect to water vapour
It was found that the difference in topography between northwest and southeast plays an important role for the effective peak supersaturation in clouds formed in the vicinity of the JFJ, while differences in the number concentration of potential cloud condensation nuclei (CCN) only play a minor role
Hammer et al.: Cloud activation behaviour at a high-alpine site when the CCN number concentration is lower (Twomey, 1977). This increases the amount of solar radiation reflected by the clouds, since distributing the available liquid water among more droplets increases the total cloud droplet surface area which results in an increased cloud albedo
Summary
Cloud droplets may form when aerosol particles are exposed to air that is supersaturated with respect to water vapour. Hammer et al.: Cloud activation behaviour at a high-alpine site when the CCN number concentration is lower (Twomey, 1977) This increases the amount of solar radiation reflected by the clouds, since distributing the available liquid water among more droplets increases the total cloud droplet surface area which results in an increased cloud albedo. Smaller droplets have a lower fall velocity, which reduces the auto-conversion rate, suppressing the formation of precipitation and increasing the lifetime of clouds (Albrecht, 1989). Changes of these indirect aerosol effects on climate, caused by anthropogenic activities, result, on a global scale, in a negative radiative forcing (IPCC, 2007). The scientific understanding of these effects is low and the resulting uncertainties of the radiative forcing are large (IPCC, 2007)
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