A12C-05
Ice nucleation by plant structural materials and its potential contribution to glaciation in clouds

Monday, 14 December 2015: 11:20
3008 (Moscone West)
Naruki Hiranuma1, Corinna Hoose2, Emma Järvinen1, Alexei A Kiselev1, Ottmar Moehler1, Martin Schnaiter1, Romy Ulrich1, Daniel J Cziczo3, Laura Felgitsch4, Kulkarni Gourihar5, Hinrich Grothe4, Naama Reicher6, Yinon Rudich6, Yutaka Tobo7 and Maria A Zawadowicz8, (1)KIT, Institute for Meteorology and Climate Research, Atmospheric Aerosol Research (IMK-AAF), Karlsruhe, Germany, (2)Karlsruhe Institute of Technology, Karlsruhe, Germany, (3)MIT--EAPS, Cambridge, MA, United States, (4)Vienna University of Technology, Vienna, Austria, (5)Pacific Northwest National Laboratory, Richland, WA, United States, (6)Weizmann Institute of Science, Rehovot, Israel, (7)NIPR National Institute of Polar Research, Tokyo, Japan, (8)Massachusetts Institute of Technology, Cambridge, MA, United States
Abstract:
Glaciation of supercooled clouds through immersion freezing is an important atmospheric process affecting the formation of precipitation and the Earth’s energy budget. Currently, the climatic impact of ice-nucleating particles (INPs) is being reassessed due to increasing evidence of their diversity and abundance in the atmosphere as well as their ability to influence cloud properties. Recently, it has been found that microcrystalline cellulose (MCC; extracted from natural wood pulp) can act as an efficient INP and may add crucial importance to quantify the role of primary biological INP (BINP) in the troposphere. However, it is still unclear if the laboratory results of MCC can be representatively scaled up to the total cellulose content in the atmosphere to assess the overall role of BINPs in clouds and the climate system. Here, we use the AIDA (Aerosol Interaction and Dynamics in the Atmosphere) cloud simulation chamber in Karlsruhe, Germany to demonstrate that several important plant constituents as well as natural plant debris can act as BINPs in simulated super-cooled clouds of the lower and middle troposphere. More specifically, we measured the surface-scaled ice nucleation activity of a total 16 plant structural materials (i.e., celluloses, lignins, lipids and carbohydrates), which were dispersed and immersed in cloud droplets in the chamber, and compared to that of dried leaf powder as a model proxy for atmospheric BINPs. Using these surface-based activities, we developed parameters describing the ice nucleation ability of these particles. Subsequently, we applied them to observed airborne plant debris concentrations and compared to the background INP simulated in a global aerosol model. Our results suggest that cellulose is the most active BINPs amongst the 16 materials and the concentration of ice nucleating cellulose and plant debris to become significant (>0.1 L-1) below about -20 ˚C. Overall, our findings support the view that MCC may be a good proxy for inferring ice nucleating properties of natural plant debris. More atmospheric observations of airborne cellulose-containing particles are necessary to allow better estimates of their effects on clouds and the global climate.

Acknowledgement: We acknowledge support by German Research Society (DFG) and Ice Nuclei research UnIT (FOR 1525 INUIT).

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