Micrometer-sized ice particles for planetary-science experiments - I. Preparation, critical rolling friction force, and specific surface energy

Abstract

Coagulation models assume a higher sticking threshold for micrometer-sized ice particles than for micrometer-sized silicate particles. However, in contrast to silicates, laboratory investigations of the collision properties of micrometer-sized ice particles (in particular, of the most abundant water ice) have not been conducted yet. Thus, we used two different experimental methods to produce micrometer-sized water ice particles, i. e. by spraying water droplets into liquid nitrogen and by spraying water droplets into a cold nitrogen atmosphere. The mean particle radii of the ice particles produced with these experimental methods are (1.49 0.79) \, μ m and (1.45 0.65) \, μ m. Ice aggregates composed of the micrometer-sized ice particles are highly porous (volume filling factor: φ = 0.11 0.01) or rather compact (volume filling factor: φ = 0.72 0.04), depending on the method of production. Furthermore, the critical rolling friction force of FRoll,ice=(114.8 23.8) × 10-10\, N was measured for micrometer-sized ice particles, which exceeds the critical rolling friction force of micrometer-sized SiO2 particles (FRoll,SiO2=(12.1 3.6) × 10-10\, N). This result implies that the adhesive bonding between micrometer-sized ice particles is stronger than the bonding strength between SiO2 particles. An estimation of the specific surface energy of micrometer-sized ice particles, derived from the measured critical rolling friction forces and the surface energy of micrometer-sized SiO2 particles, results in γice = 0.190 \, J \, m-2.