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Abstract
Phase changes of sea salt particles alter their physical and chemical properties, which is significant for Earth’s chemistry and energy budget. In this study, a continuous flow diffusion chamber is used to investigate deliquescence, homogeneous and heterogeneous ice nucleation between 242 K and 215 K, of four salts: pure NaCl, pure MgCl2, synthetic sea water salt, and salt distilled from sampled sea water. Anhydrous particles, aqueous droplets and ice particles were discriminated using a polarisation-sensitive optical particle counter coupled with a machine learning analysis technique. The measured onset deliquescence relative humidities agree with previous studies, where sea water salts deliquescence at lower humidities than pure NaCl. Deliquesced salt droplets homogenously freeze when the relative humidity reaches a sufficiently high value at temperatures below 233 K. From 224 K and below, deposition nucleation freezing on a fraction of NaCl particles was observed at humidities lower than the deliquescence relative humidity. At these low temperatures, otherwise unactivated salt particles deliquesced at the expected deliquescence point, followed by homogeneous freezing at temperatures as low as 215 K. Thus, the observed sea salt particles exhibit a triad of temperature-dependent behaviours. First, they act as cloud condensation particles (CCNs) > 233 K, second they can be homogeneous freezing nuclei (HFNs) < 233 K and finally they act as ice nucleating particles (INPs) for heterogeneous nucleation <224 K.
Highlights
Sea salt particles are abundant in the atmosphere (O’Dowd et al, 1997), important to the terrestrial radiation budget, act as cloud nuclei and participate in heterogeneous halogen chemistry (Abbatt et al, 2012; Gantt and Meskhidze, 2013)
Sea salt particles take up water close to the deliquescence relative humidity (DRH) of pure NaCl (Martin, 2000; Wise et al, 2009), ~75% at 293 K (Tang and Munkelwitz, 1993), which makes sea salt particles efficient cloud condensation nuclei (CCNs)
We present an exploration of the NaCl system using a low-temperature continuous flow diffusion chamber (CFDC), which allows us to study phase changes under conditions of atmospheric interests and illustrates the potential application of the CFDC in detecting various phase changes in the ambient atmosphere
Summary
Sea salt particles are abundant in the atmosphere (O’Dowd et al, 1997), important to the terrestrial radiation budget, act as cloud nuclei and participate in heterogeneous halogen chemistry (Abbatt et al, 2012; Gantt and Meskhidze, 2013). Sea salt particles take up water close to the deliquescence relative humidity (DRH) of pure NaCl (Martin, 2000; Wise et al, 2009), ~75% at 293 K (Tang and Munkelwitz, 1993), which makes sea salt particles efficient cloud condensation nuclei (CCNs). Sea salt particles/droplets can act as either homogeneous freezing nuclei (HFNs) or ice nucleating particles (INPs), depending on whether deliquescence overcomes ice nucleation or vice versa (Wise et al, 2012). Sea salt particles have been observed to contribute to cirrus cloud formation, especially over open oceans where deep convection is present, to loft particles from the surface, high into the atmosphere (Cziczo et al, 2004; Twohy and Poellot, 2005; Cziczo et al, 2013)
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