The origin of midlatitude ice clouds and the resulting influence on their microphysical properties

Luebke, Anna; Spelten, N.; Baumgardner, D.; Krämer, M.; Avallone, L. M.; Meyer, J.; Afchine, A.; Costa, A.; Rolf, C.

doi:10.5194/acpd-15-34243-2015

Journal Article

FZJ-2015-07479

The origin of midlatitude ice clouds and the resulting influence on their microphysical properties

Luebke, A. (Corresponding author)FZJ* ; Afchine, A.FZJ* ; Costa, A.FZJ* ; Meyer, J. ; Rolf, C.FZJ* ; Spelten, N.FZJ* ; Avallone, L. M. ; Baumgardner, D. ; Krämer, M.FZJ*

2015
EGU Katlenburg-Lindau

Atmospheric chemistry and physics / Discussions 15(23), 34243 - 34281 (2015) [10.5194/acpd-15-34243-2015]

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Please use a persistent id in citations: http://hdl.handle.net/2128/9576 doi:10.5194/acpd-15-34243-2015

Abstract: The radiative role of ice clouds in the atmosphere is known to be important, but uncertainties remain concerning the magnitude and net effects. However, through measurements of the microphysical properties of cirrus clouds, we can better characterize them, which can ultimately allow for their radiative properties to be more accurately ascertained. It has recently been proposed that there are two types of cirrus clouds – in situ and liquid origin. In this study, we present observational evidence to show that two distinct types of cirrus do exist. Airborne, in situ measurements of cloud ice water content (IWC), ice crystal concentration (Nice), and ice crystal size from the 2014 ML-CIRRUS campaign provide cloud samples that have been divided according to their origin type. The key features that set liquid origin cirrus apart from the in situ origin cirrus are a higher frequency of high IWC (> 100 ppmv), higher Nice values, and larger ice crystals. A vertical distribution of Nice shows that the in situ origin cirrus clouds exhibit a median value of around 0.1 cm−3, while the liquid origin concentrations are slightly, but notably higher. The median sizes of the crystals contributing the most mass are less than 200 μm for in situ origin cirrus, with some of the largest crystals reaching 550 μm in size. The liquid origin cirrus, on the other hand, were observed to have median diameters greater than 200 μm, and crystals that were up to 750 μm. An examination of these characteristics in relation to each other and their relationship to temperature provides strong evidence that these differences arise from the dynamics and conditions in which the ice crystals formed. Additionally, the existence of these two groups in cirrus cloud populations may explain why a bimodal distribution in the IWC-temperature relationship has been observed. We hypothesize that the low IWC mode is the result of in situ origin cirrus and the high IWC mode is the result of liquid origin cirrus.

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