Role of Nanoscale Interfacial Proximity in Contact Freezing in Water

TL;DR

This study reveals that nanoscale proximity between ice nucleating particles and water interfaces significantly accelerates ice formation, especially in water with surface freezing tendencies, through a mechanism involving hourglass-shaped nuclei.

Contribution

It demonstrates that nanoscale proximity alone can enhance ice nucleation rates and links this effect to surface freezing propensity, introducing a new mechanistic understanding.

Findings

Nanoscale proximity induces rate increases in ice nucleation.

Surface freezing propensity enhances nucleation via nanoscale effects.

Nucleation involves hourglass-shaped crystalline nuclei.

Abstract

Contact freezing is a mode of atmospheric ice nucleation in which a collision between a dry ice nucleating particle (INP) and a water droplet results in considerably faster heterogeneous nucleation. The molecular mechanism of such enhancement is, however, still a mystery. While earlier studies had attributed it to collision-induced transient perturbations, recent experiments point to the pivotal role of nanoscale proximity of the INP and the free interface. By simulating heterogeneous nucleation of ice within INP-supported nanofilms of two model water-like tetrahedral liquids, we demonstrate that such nanoscale proximity is sufficient for inducing rate increases commensurate with those observed in contact freezing experiments, but only if the free interface has a tendency to enhance homogeneous nucleation. Water is suspected of possessing this latter property, known as surface freezing propensity. Our findings therefore establish a connection between surface freezing propensity and kinetic enhancement during contact nucleation. We also observe that faster nucleation proceeds through a mechanism markedly distinct from classical heterogeneous nucleation, involving the formation of hourglass-shaped crystalline nuclei that conceive at either interface, and that have a lower free energy of formation due to the nanoscale proximity of the interfaces and the modulation of the free interfacial structure by the INP. In addition to providing valuable insights into the physics of contact nucleation, our findings can assist in improving the accuracy of heterogeneous nucleation rate measurements in experiments, and in advancing our understanding of ice nucleation on nonuniform surfaces such as organic, polymeric and biological materials.