Abstract
Abstract. The phase state of atmospheric aerosols has an impact on their chemical aging and their deliquescence and thus their ability to act as cloud condensation nuclei (CCN). The phase change of particles can be induced by the deliquescence or efflorescence of water or by chemical aging. Existing methods, such as tandem differential mobility analysis rely on the size change of particles related to the water uptake or release. To address the need to study the phase change induced by mass-preserving and nearly mass-preserving processes a new method has been developed. The method relies on the physical impaction of particles on a smooth substrate and subsequent counting of bounced particles by a condensation particle counter (CPC). The connection between the bounce probability and physical properties of particles is so far qualitative. To evaluate the performance of this method, the phase state of ammonium sulfate and levoglucosan, crystalline and amorphous solid, in the presence of water vapor was studied. The results show a marked difference in particle bouncing properties between substances – not only at the critical relative humidity level, but also on the slope of the bouncing probability with respect to humidity. This suggests that the method can be used to differentiate between amorphous and crystalline substances as well as to differentiate between liquid and solid phases.
Highlights
Particle deliquescence plays an important role in cloud condensation dynamics and is studied widely
Common methods to investigate particle-water interaction are the use of hygroscopicity tandem DMA, (HTDMA) (Rader and Mc-Murry, 1986; Liu et al, 1978) and cloud condensation nucleus counter (CCN-counter) (Hudson, 1993; Roberts and Nenes, 2005)
These methods rely on detecting the size change of particles as they are deliquesced in HDTMA according to the Köhler theory, or activated to larger droplets in cloud condensation nuclei (CCN)-counter
Summary
Particle deliquescence plays an important role in cloud condensation dynamics and is studied widely. 1986; Liu et al, 1978) and cloud condensation nucleus counter (CCN-counter) (Hudson, 1993; Roberts and Nenes, 2005) These methods rely on detecting the size change of particles as they are deliquesced in HDTMA according to the Köhler theory, or activated to larger droplets in CCN-counter. The notable size change steps in the HTDMA spectrum is used to determine the efflorescence and deliquescence relative humidity (ERH and DRH) (Seinfeld et al, 1998). These methods, can not distinguish the phase state of the particles. The method is, constrained to large particles, typically 2–50 μm
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