Atomistic Simulations of Wetting Dynamics of Water Nanodroplets on Nanotextured Titanium: Implications for Medical Implants

TL;DR

This study uses atomistic simulations to explore how water nanodroplets interact with nanotextured titanium surfaces, revealing transitions in wetting states and highlighting the limitations of classical models for nanoscale wetting behavior.

Contribution

It provides detailed atomistic insights into water-titanium interactions on nanotextured surfaces, advancing understanding of wetting dynamics relevant for biomedical implants.

Findings

Transition from Wenzel to Cassie-Baxter wetting states with increased roughness

Damping of nanodroplet vibrations on rough surfaces

Decreased interaction energy correlating with increased roughness

Abstract

The development of high-performance biomedical implants requires a deep understanding of the molecular interactions between water molecules and titanium (Ti) surfaces. In this study, fully atomistic molecular dynamics simulations were used to study the static and dynamic wetting behavior of water nanodroplets on both flat and femtosecond laser-induced nanotextured Ti surfaces. Our findings reveal a clear transition from Wenzel to Cassie-Baxter wetting states as surface roughness increases, significantly affecting droplet spreading. We also observe the damping of nanodroplet vibrations and a roughness-dependent shift toward hydrophobicity, driven by stronger atomic interactions between water molecules and surface atoms. Furthermore, the interaction energy between water droplets and nano-textured Ti surfaces decreases with increasing roughness, reinforcing the observed changes in wettability. The discrepancies observed between classical wetting models and nanoscale behavior emphasize the limitations of current theoretical approaches and the importance of developing more advanced models. This study provides valuable insights into optimizing Ti surface properties for improved implant performance through controlled wettability.