Heterogeneous ice nucleation of α‐pinene SOA particles before and after ice cloud processing

The ice nucleation ability of α‐pinene secondary organic aerosol (SOA) particles was investigated at temperatures between 253 and 205 K in the Aerosol Interaction and Dynamics in the Atmosphere cloud simulation chamber. Pristine SOA particles were nucleated and grown from pure gas precursors and the...

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Veröffentlicht in:Journal of geophysical research. Atmospheres 2017-05, Vol.122 (9), p.4924-4943
Hauptverfasser: Wagner, Robert, Höhler, Kristina, Huang, Wei, Kiselev, Alexei, Möhler, Ottmar, Mohr, Claudia, Pajunoja, Aki, Saathoff, Harald, Schiebel, Thea, Shen, Xiaoli, Virtanen, Annele
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Sprache:eng
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Zusammenfassung:The ice nucleation ability of α‐pinene secondary organic aerosol (SOA) particles was investigated at temperatures between 253 and 205 K in the Aerosol Interaction and Dynamics in the Atmosphere cloud simulation chamber. Pristine SOA particles were nucleated and grown from pure gas precursors and then subjected to repeated expansion cooling cycles to compare their intrinsic ice nucleation ability during the first nucleation event with that observed after ice cloud processing. The unprocessed α‐pinene SOA particles were found to be inefficient ice‐nucleating particles at cirrus temperatures, with nucleation onsets (for an activated fraction of 0.1%) as high as for the homogeneous freezing of aqueous solution droplets. Ice cloud processing at temperatures below 235 K only marginally improved the particles' ice nucleation ability and did not significantly alter their morphology. In contrast, the particles' morphology and ice nucleation ability was substantially modified upon ice cloud processing in a simulated convective cloud system, where the α‐pinene SOA particles were first activated to supercooled cloud droplets and then froze homogeneously at about 235 K. As evidenced by electron microscopy, the α‐pinene SOA particles adopted a highly porous morphology during such a freeze‐drying cycle. When probing the freeze‐dried particles in succeeding expansion cooling runs in the mixed‐phase cloud regime up to 253 K, the increase in relative humidity led to a collapse of the porous structure. Heterogeneous ice formation was observed after the droplet activation of the collapsed, freeze‐dried SOA particles, presumably caused by ice remnants in the highly viscous material or the larger surface area of the particles. Key Points Pristine α‐pinene SOA particles reveal poor heterogeneous ice nucleation ability in the cirrus cloud regime of the upper troposphere Ice cloud processing of α‐pinene SOA particles in a convective cloud system leads to formation of highly porous particles Freeze‐dried SOA particles show heterogeneous ice formation in the mixed‐phase cloud regime via the CCN‐induced ice growth mode
ISSN:2169-897X
2169-8996
DOI:10.1002/2016JD026401