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dc.contributor.authorBarrett, Paul
dc.contributor.authorBlyth, Alan
dc.contributor.authorBrown, Phil
dc.contributor.authorUlanowski, Zbigniew
dc.date.accessioned2017-06-28T10:58:30Z
dc.date.available2017-06-28T10:58:30Z
dc.date.issued2015-04-12
dc.identifier.citationBarrett , P , Blyth , A , Brown , P & Ulanowski , Z 2015 , ' Observations of small ice in mixed phase clouds using and airborne SID2 Small Ice Detector ' , European Geosciences Union General Assembly , Vienna , Austria , 12/04/15 - 17/04/15 .
dc.identifier.citationconference
dc.identifier.otherPURE: 9787726
dc.identifier.otherPURE UUID: bf9cc077-ec0b-40b8-b895-a8965c733d90
dc.identifier.otherORCID: /0000-0003-4761-6980/work/62748729
dc.identifier.urihttp://hdl.handle.net/2299/18603
dc.descriptionPaul Barrett, Alan Blyth, Phil Brown, Zbigniew Ulanowski, ‘Observations of small ice in mixed phase clouds using and airborne SID2 Small Ice Detector’, poster presented at the European Geosciences Union General Assembly, Vienna, Austria, 12-17 April, 2015.
dc.description.abstractHere we present observations of small ice crystals in mixed phase cloud systems using an aircraft mounted SID2 (Small Ice Detector 2) probe. It is likely that these small ice particles have formed through an immersion freezing process from the underlying liquid cloud population. The exact nature of the immersion freezing mechanisms at work in the real atmosphere are uncertain and may include contributions from singular and stochastic processes as well as hybrid processes such as Contact Nucleation Inside Out. Observations of the number and position in the cloud structure of the first ice in mixed phase clouds are essential if we are to understand the microphysical mechanisms responsible for the conversion of liquid cloud drops into ice particles. The SID2 probe is able to observe particles smaller a than 10 microns and so is useful when assessing the properties of ice that has formed from liquid cloud particles. Using the scattering patterns produced by SID2 it is possible to distinguish between liquid drops and non-spherical particles . A liquid cloud drop will produce a scattering pattern containing concentric rings whereas a non-spherical particle will not. The SID2 probe has a relatively large sample volume, and while this is good in the low concentrations found in typical cirrus clouds it presents difficulties in liquid clouds where concentrations can be orders of magnitude greater. Coincidence events, where two or more spherical particles are co-located within the extended sample volume, do not produce the typical scattering pattern associated with a liquid particle and are therefore more difficult to distinguish from ice. There are, however, some characteristic features of the scattering pattern from a coincidence event. Here we present an algorithm to identify coincidence events from analysis of individual scattering patterns. Results are presented that show that it is possible to obtain an estimate of the concentration of small ice in clouds which have relatively low concentrations of liquid cloud drops (<100/cc). Observations are presented of small ice in a mixed phase altocumulus cloud relative to cloud top. The significance of these observations and the likelihood of the potential freezing mechanism is discussed.en
dc.language.isoeng
dc.titleObservations of small ice in mixed phase clouds using and airborne SID2 Small Ice Detectoren
dc.contributor.institutionSchool of Physics, Astronomy and Mathematics
dc.contributor.institutionCentre for Atmospheric and Climate Physics Research
dc.contributor.institutionLight Scattering and Radiative Processes
dc.contributor.institutionScience & Technology Research Institute
dc.description.statusNon peer reviewed
rioxxterms.typeOther
herts.preservation.rarelyaccessedtrue


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