Investigations into the complete spreading dynamics of a viscoelastic drop on a spherical substrate

TL;DR

This study combines theoretical modeling and experimental validation to explore how viscoelastic non-Newtonian drops spread on spherical substrates, revealing the influence of viscoelasticity on contact angle and wetting time.

Contribution

It introduces a comprehensive analysis of viscoelastic drop spreading on spherical surfaces, including experimental validation and insights into late-stage spreading dynamics.

Findings

Higher viscoelasticity increases viscous dissipation and wetting time.

Elastic fluids exhibit larger dynamic contact angles than Newtonian fluids.

Complete wetting time extends with increased viscoelasticity.

Abstract

We study the spreading dynamics of a sphere-shaped elastic non-Newtonian liquid drop on a spherical substrate in the capillary driven regime. We use the simplified Phan Thien Tanner model to represent the rheology of the elastic non-Newtonian drop. We consider the drop to be a crater on a flat substrate to calculate the viscous dissipation near the contact line. Following the approach compatible with the capillary-viscous force balance, we establish the evolution equation for describing the temporal evolution of the contact line during spreading. We show that the contact line velocity obtained from the theoretical calculation matches well with our experimental observations. Also, as confirmed by the present experimental observations, our analysis deems efficient to capture the phenomenon during the late-stage of spreading for which the effect of line tension becomes dominant. An increment in the viscoelastic parameter of the fluid increases the viscous dissipation effect at the contact line. It is seen that the higher dissipation effect leads to an enhancement in the wetting time of the drop on the spherical substrate. Also, we have shown that the elastic nature of fluid leads to an increment in the dynamic contact angle at any temporal instant as compared to its Newtonian counterpart. Finally, we unveil that the phenomenon of increasing contact angle results in the time required for the complete wetting of drop becomes higher with increasing viscoelasticity of the fluid. This article will fill a gap still affecting the existing literature due to the unavailability of experimental investigations of the spreading of the elastic non-Newtonian drop on a spherical substrate.