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UP: Fachverband Umweltphysik
UP 2: Clouds and Aerosols
UP 2.3: Vortrag
Donnerstag, 2. September 2021, 14:35–14:50, H3
Cracking the problem of atmospheric ice nucleation: chemically induced fracturing of alkali feldspar makes it a better ice-nucleating aerosol particle — •Tilia Gädeke1, Alexei Kiselev1, Alice Keinert1, Thomas Leisner1, Christoph Sutter2, Elena Petrisheva3, and Rainer Abart3 — 1KIT, IMK-AAF, Karlsruhe, Germany — 2Universität Heidelberg, IFU, Heidelberg, Germany — 3University of Vienna, Department of Lithospheric Research, Vienna, Austria
Feldspar is a major constituent of magmatic, metamorphic, and sedimentary rocks on the Earths* surface. Consequently it is also an abundant constituent of the solid aerosol particles and induces heterogeneous freezing in cloud droplets. The freezing process changes cloud properties and precipitation formation. The mineralogy of feldspar has a crucial effect on its ability to induce freezing of water. The mechanisms relating the microstructure of feldspars and enhanced ice nucleation (IN) efficacy are not known and are currently debated.
The particularly high IN activity of alkali feldspar has been attributed to structural similarities between specific prism planes of ice and feldspar. In this study, the gem quality K-rich alkali feldspar was shifted towards more Na-rich compositions. The cation exchange induces parallel cracks with an orientation close to (100). Droplet freezing assay experiments performed on the cation-exchanged feldspars, revealed an increase of freezing efficacy with respect to the untreated feldspar. This contribution demonstrates how the natural complexity of rock-forming minerals can have a direct impact on Earth's climate.