Abstract
Abstract. Water uptake by aerosol particles controls their ability to form cloud droplets, and reconciliation between different techniques for examining cloud condensation nuclei (CCN) properties is important to our understanding of these processes and our ability to measure and predict them. Reconciliation between measurements of sub-saturated and supersaturated aerosol particle water uptake was attempted at a wide range of locations between 2007 and 2013. The agreement in derived number of CCN (NCCN or particle hygroscopicity was mixed across the projects, with some data sets showing poor agreement across all supersaturations and others agreeing within errors for at least some of the supersaturation range. The degree of reconciliation did not seem to depend on the environment in which the measurements were taken. The discrepancies can only be attributable to differences in the chemical behaviour of aerosols and gases in each instrument, leading to under- or overestimated growth factors and/or CCN counts, though poorer reconciliation at lower supersaturations can be attributed to uncertainties in the size distribution at the threshold diameter found at these supersaturations. From a single instrument, the variability in NCCN calculated using particle hygroscopicity or size distribution averaged across a project demonstrates a greater sensitivity to variation in the size distribution than chemical composition in most of the experiments. However, the discrepancies between instruments indicate a strong requirement for reliable quantification of CCN in line with an improved understanding of the physical processes involved in their measurement. Without understanding the reason for discrepancies in the measurements, it is questionable whether quantification of CCN behaviour is meaningful.
Highlights
Changes to the number of cloud condensation nuclei (CCN) will impact on cloud microphysical properties, with an increase in CCN resulting in more and smaller cloud droplets and in brighter clouds (Twomey, 1977) with longer lifetimes, higher liquid water content and increased cloud thickness (Stevens and Feingold, 2009)
These were derived from the differential mobility analyser (DMA) and condensation particle counter (CPC) attached to the cloud condensation nuclei counter (CCNc)
These show a wide variation in the aerosol size distributions between the different campaigns, and a wide variation can be seen in the GF distributions from the Hygroscopicity Tandem Differential Mobility Analyser (HTDMA) measurements, which are shown in the Supplement for each experiment, and are reported for 90 % RH at all locations
Summary
Changes to the number of cloud condensation nuclei (CCN) will impact on cloud microphysical properties, with an increase in CCN resulting in more and smaller cloud droplets and in brighter clouds (Twomey, 1977) with longer lifetimes, higher liquid water content and increased cloud thickness (Stevens and Feingold, 2009). The net effect of these aerosol–cloud interactions is to cool the climate system, significant uncertainties remain in predicting the magnitude of this impact (Boucher et al, 2013). A better understanding of these interactions is needed to improve climate predictions. A number of regional and global models have been developed over recent years to predict CCN number concentrations based on these parameters In order to verify and improve these models, measurements of CCN properties from a wide range of locations around the world are needed
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