Litcius/Paper detail

Atomic structure and water arrangement on K-feldspar microcline (001)

Tobias Dickbreder, Franziska Sabath, Bernhard Reischl, Rasmus Nilsson, Adam S. Foster, Ralf Bechstein, Angelika Kühnle

2023Nanoscale11 citationsDOIOpen Access PDF

Abstract

, caused by ice nucleating particles such as mineral dusts or organic aerosols. In this regard, K-feldspar minerals have attracted great interest recently as they have been identified as one of the most important ice nucleating particles under mixed-phase cloud conditions. The mechanism by which feldspar minerals facilitate ice nucleation remains, however, elusive. Here, we present atomic force microscopy (AFM) experiments on microcline (001) performed in an ultrahigh vacuum and at the solid-water interface together with density functional theory (DFT) and molecular dynamics (MD) calculations. Our ultrahigh vacuum data reveal features consistent with a hydroxyl-terminated surface. This finding suggests that water in the residual gas readily reacts with the surface. Indeed, the corresponding DFT calculations confirm a dissociative water adsorption. Three-dimensional AFM measurements performed at the mineral-water interface unravel a layered hydration structure with two features per surface unit cell. A comparison with MD calculations suggests that the structure observed in AFM corresponds to the second hydration layer rather than the first water layer. In agreement with previous computation results, no ice-like structure is seen, questioning an explanation of the ice nucleation ability by lattice match. Our results provide an atomic-scale benchmark for the clean and water-covered microcline (001) plane, which is mandatory for understanding the ice nucleation mechanism on feldspar minerals.

Topics & Concepts

MicroclineFeldsparMaterials scienceCrystallographyChemistryMetallurgyQuartzSpectroscopy and Quantum Chemical StudiesNMR spectroscopy and applicationsClay minerals and soil interactions