Morphological Transitions during Melting of Small Cylindrical Aggregates

TL;DR

This study investigates the complex melting behaviors of small cylindrical aggregates on planar surfaces, emphasizing the role of capillary interfaces and morphological transitions, with implications for understanding melting in confined systems.

Contribution

It introduces a detailed analysis of capillary-driven morphological transitions during melting, including the coexistence of different shapes and their impact on melting points.

Findings

Capillary instability leads to distinct morphological states during melting.

Melting points vary with aggregate shape and volume fraction.

Insights into melting pathways for anisotropic wetting behaviors.

Abstract

Most studies on melting under confinement focus only on the solid and liquid melt phases. Despite of its ubiquity, contributions from the capillary interface (liquid / vapor interface) are often neglected. In this study the melting behavior of small cylindrical aggregates in vapor attached to planar surfaces is analyzed. For the assumed boundary conditions (cylindrical solid with a non wetting top plane and a wettable side wall) solid and the liquid phases can coexist within a certain temperature range. Due to capillary instability, the liquid phase can form either an axisymmetric rouloid morphology or, above a certain threshold liquid volume fraction, a bulge coexisting with a rouloid-like section. The corresponding melting points are different. The analysis explicitly describes the behavior of a real system of small aggregates of long chain alkanes on planar substrates. It also gives qualitative insights into the melting behavior of small aggregates with anisotropic wetting behaviors in general. It reveals in particular how melting points and melting pathways depend on the energetic respectively morphological pathways leading to complete melting.